Methods and compositions for the making and using of guide nucleic acids

ABSTRACT

Provided herein are methods and compositions to make guide nucleic acids (gNAs), nucleic acids encoding gNAs, collections of gNAs, and nucleic acids encoding for a collection of gNAs from any source nucleic acid. Also provided herein are methods and compositions to use the resulting gNAs, nucleic acids encoding gNAs, collections of gNAs, and nucleic acids encoding for a collection of gNAs in a variety of applications.

CROSS-REFERENCE

This is a U.S. National Stage Application under 35 U.S.C. § 371 of International Application No. PCT/US2016/065420, filed on Dec. 7, 2016, which claims the benefit of U.S. Provisional Application No. 62/264,262, filed Dec. 7, 2015, and of U.S. Provisional Application No. 62/298,963, filed Feb. 23, 2016, each of which is hereby incorporated by reference in its entirety.

INCORPORATION BY REFERENCE OF SEQUENCE LISTING

The present application is being filed with a Sequence Listing in electronic format. The Sequence Listing is provided as a file entitled ARCB-003/02US_SeqList.txt, created Nov. 19, 2018, which is 816,892 bytes in size. The information in electronic format of the Sequence Listing is incorporated by reference in its entirety.

BACKGROUND

Human clinical DNA samples and sample libraries such as cDNA libraries derived from RNA contain highly abundant sequences that have little informative value and increase the cost of sequencing. While methods have been developed to deplete these unwanted sequences (e.g., via hybridization capture), these methods are often time-consuming and can be inefficient.

Although a guide nucleic acid (gNA) mediated nuclease systems (such as guide RNA (gRNA)-mediated Cas systems) can efficiently deplete any target DNA, targeted depletion of very high numbers of unique DNA molecules is not feasible. For example, a sequencing library derived from human blood may contain >99% human genomic DNA. Using a gRNA-mediated Cas9 system-based method to deplete this genomic DNA to detect an infectious agent circulating in the human blood would require extremely high numbers of gRNAs (about 10-100 million gRNAs), in order to ensure that a gRNA will be present every 30-50 base pairs (bp), and that no target DNA will be missed. Very large numbers of gRNAs can be predicted computationally and then synthesized chemically, but at a prohibitively expensive cost.

Therefore, there is a need in the art to provide a cost-effective method of converting any DNA into a gNA (e.g., gRNA) library to enable, for example, genome-wide depletion of unwanted DNA sequences from those of interest, without prior knowledge about their sequences. Provided herein are methods and compositions that address this need.

SUMMARY

Provided herein are compositions and methods to generate gNAs and collections of gNAs from any source nucleic acid. For example, gRNAs and collections of gRNAs can be generated from source DNA, such as genomic DNA. Such gNAs and collections of the same are useful for a variety of applications, including depletion, partitioning, capture, or enrichment of target sequences of interest, genome-wide labeling, genome-wide editing, genome-wide functional screens, and genome-wide regulation.

In one aspect, the invention described herein provides a collection of nucleic acids, a plurality of the nucleic acids in the collection comprising: a first segment comprising a regulatory region; a second segment encoding a targeting sequence; and a third segment encoding a nucleic acid-guided nuclease system protein-binding sequence, wherein at least 10% of the nucleic acids in the collection vary in size. In another aspect, the invention described herein provides a collection of nucleic acids, a plurality of the nucleic acids in the collection comprising: a first segment comprising a regulatory region; a second segment encoding a targeting sequence, wherein the size of the second segment is greater than 21 bp; and a third segment encoding a nucleic acid-guided nuclease system protein-binding sequence. In some embodiments, the nucleic acid-guided nuclease system protein is a CRISPR/Cas system protein. In some embodiments, the size of the second segment varies from 15-250 bp across the collection of nucleic acids. In some embodiments, at least 10% of the second segments in the collection are greater than 21 bp. In some embodiments, the size of the second segment is not 20 bp. In some embodiments, the size of the second segment is not 21 bp. In some embodiments, the collection of nucleic acids is a collection of DNA. In some embodiments, the second segment is single stranded DNA. In some embodiments, the third segment is single stranded DNA. In some embodiments, the second segment is double stranded DNA. In some embodiments, the third segment is double stranded DNA. In some embodiments, the regulatory region is a region capable of binding a transcription factor. In some embodiments, the regulatory region comprises a promoter. In some embodiments, the promoter is selected from the group consisting of T7, SP6, and T3. In some embodiments, the targeting sequence is directed at a mammalian genome, eukaryotic genome, prokaryotic genome, or a viral genome. In some embodiments, the targeting sequence is directed at repetitive or abundant DNA. In some embodiments, the targeting sequence is directed at mitochondrial DNA, ribosomal DNA, Alu DNA, centromeric DNA, SINE DNA, LINE DNA, or STR DNA. In some embodiments, the sequence of the second segments is selected from Table 3 and/or Table 4. In some embodiments, the collection comprises at least 10² unique nucleic acid molecules. In some embodiments, the targeting sequence is at least 80% complementary to the strand opposite to a sequence of nucleotides 5′ to a PAM sequence. In some embodiments, the collection comprises targeting sequences directed to sequences of interest spaced about every 10,000 bp or less across the genome of an organism. In some embodiments, the PAM sequence is AGG, CGG, or TGG. In some embodiments, the PAM sequence is specific for a CRISPR/Cas system protein selected from the group consisting of Cas9, Cpf1, Cas3, Cas8a-c, Cas10, Cse1, Csy1, Csn2, Cas4, Csm2, and Cm5. In some embodiments, the third segment comprises DNA encoding a gRNA stem-loop sequence. In some embodiments, the third segment encodes for a RNA comprising the sequence GUUUUAGAGCUAGAAAUAGCAAGUUAAAAUAAGGCUAGUCCGUUAUCAACUUGAAAAAGUGGCA CCGAGUCGGUGCUUUUUUU (SEQ ID NO: 1) or encodes for a RNA comprising the sequence GUUUUAGAGCUAUGCUGGAAACAGCAUAGCAAGUUAAAAUAAGGCUAGUCCGUUAUCAACUUGA AAAAGUGGCACCGAGUCGGUGCUUUUUUUC (SEQ ID NO: 2). In some embodiments, the sequence of the third segment encodes for a crRNA and a tracrRNA. In some embodiments, the nucleic acid-guided nuclease system protein is from a bacterial species. In some embodiments, the nucleic acid-guided nuclease system protein is from an archaea species. In some embodiments, the CRISPR/Cas system protein is a Type I, Type II, or Type III protein. In some embodiments, the CRISPR/Cas system protein is selected from the group consisting of Cas9, Cpf1, Cas3, Cas8a-c, Cas10, Cse1, Csy1, Csn2, Cas4, Csm2, Cm5, dCas9 and cas9 nickase. In some embodiments, the third segment comprises DNA encoding a Cas9-binding sequence. In some embodiments, a plurality of third segments of the collection encode for a first nucleic acid-guided nuclease system protein binding sequence, and a plurality of the third segments of the collection encode for a second nucleic acid-guided nuclease system protein binding sequence. In some embodiments, the third segments of the collection encode for a plurality of different binding sequences of a plurality of different binding sequences of a plurality of different nucleic acid-guided nuclease system proteins.

In another aspect, the invention described herein provides for a collection of guide RNAs (gRNAs), comprising: a first RNA segment a targeting sequence; and a second RNA segment comprising a nucleic acid-guided nuclease system protein-binding sequence, wherein at least 10% of the gRNAs in the collection vary in size. In some embodiments, the nucleic acid-guided nuclease system protein is a CRISPR/Cas system protein. In some embodiments, the size of the first segment varies from 15-250 bp across the collection of gRNAs. In some embodiments, the at least 10% of the first segments in the collection are greater than 21 bp. In some embodiments, the size of the first segment is not 20 bp. In some embodiments, the size of the first segment is not 21 bp. In some embodiments, the targeting sequence is directed at a mammalian genome, eukaryotic genome, prokaryotic genome, or viral genome. In some embodiments, the targeting sequence is directed at repetitive or abundant DNA. In some embodiments, the targeting sequence is directed at mitochondrial DNA, ribosomal DNA, Alu DNA, centromeric DNA, SINE DNA, LINE DNA, or STR DNA. In some embodiments, the sequence of the first segments is RNA encoded by sequences selected from Table 3 and/or Table 4. In some embodiments, the collection comprises at least 10² unique gRNAs. In some embodiments, the gRNAs comprise cytosine, guanine, and adenine. In some embodiments, a subset of the gRNAs further comprises thymine. In some embodiments, a subset of the gRNAs further comprises uracil. In some embodiments, the first segment is at least 80% complementary to a target genomic sequence of interest. In some embodiments, the targeting sequence is at least 80% complementary to the strand opposite to a sequence of nucleotides 5′ to a PAM sequence. In some embodiments the PAM sequence is AGG, CGG, or TGG. In some embodiments, the PAM sequence is specific for a CRISPR/Cas system protein selected from the group consisting of Cas9, Cpf1, Cas3, Cas8a-c, Cas10, Cse1, Csy1, Csn2, Cas4, Csm2, and Cm5. In some embodiments, the second segment comprises a gRNA stem-loop sequence. In some embodiments, the third segment comprises DNA encoding a gRNA stem-loop sequence. In some embodiments, the third segment comprises the sequence GUUUUAGAGCUAGAAAUAGCAAGUUAAAAUAAGGCUAGUCCGUUAUCAACUUGAAAAAGUGGCA CCGAGUCGGUGCUUUUUUU (SEQ ID NO: 1) or comprises the sequence GUUUUAGAGCUAUGCUGGAAACAGCAUAGCAAGUUAAAAUAAGGCUAGUCCGUUAUCAACUUGA AAAAGUGGCACCGAGUCGGUGCUUUUUUUC (SEQ ID NO: 2). In some embodiments, the second segment comprises a crRNA and a tracrRNA. In some embodiments, the nucleic acid-guided nuclease system protein is from a bacterial species. In some embodiments, the nucleic acid-guided nuclease system protein is from an archaea species. In some embodiments, the CRISPR/Cas system protein is a Type I, Type II, or Type III protein. In some embodiments, the CRISPR/Cas system protein is selected from the group consisting of Cas9, Cpf1, Cas3, Cas8a-c, Cas10, Cse1, Csy1, Csn2, Cas4, Csm2, Cm5, dCas9 and cas9 nickase. In some embodiments, the second segment comprises a Cas9-binding sequence. In some embodiments, at least 10% of the gRNAs in the collection vary in their 5′ terminal-end sequence. In some embodiments, the collection comprises targeting sequences directed to sequences of interest spaced every 10,000 bp or less across the genome of an organism. In some embodiments, a plurality of second segments of the collection comprise a first nucleic acid-guided nuclease system protein binding sequence, and a plurality of the second segments of the collection comprise a second nucleic acid-guided nuclease system protein binding sequence. In some embodiments, the second segments of the collection comprise a plurality of different binding sequences of a plurality of different nucleic acid-guided nuclease system proteins. In some embodiments, a plurality of the gRNAs of the collection are attached to a substrate. In some embodiments, a plurality of the gRNAs of the collection comprise a label. In some particular embodiments, a plurality of the gRNAs of the collection comprise different labels.

In another aspect, the invention described herein provides nucleic acid comprising: a first segment comprising a regulatory region; a second segment encoding a targeting sequence, wherein the targeting sequence is greater than 30 bp; and a third segment encoding a nucleic acid encoding a nucleic acid-guided nuclease system protein-binding sequence. In some embodiments, the nucleic acid-guided nuclease is a CRISPR/Cas system protein. In some embodiments, the nucleic acid is DNA. In some embodiments, the second segment is single stranded DNA. In some embodiments, the third segment is single stranded DNA. In some embodiments, the second segment is double stranded DNA. In some embodiments, the third segment is double stranded DNA. In some embodiments, the regulatory region is a region capable of binding a transcription factor. In some embodiments, the regulatory region comprises a promoter. In some embodiments, the promoter is selected from the group consisting of T7, SP6, and T3. In some embodiments, the targeting sequence is directed at a mammalian genome, eukaryotic genome, prokaryotic genome, or a viral genome. In some embodiments, the targeting sequence is directed at abundant or repetitive DNA. In some embodiments, the targeting sequence is directed at mitochondrial DNA, ribosomal DNA, Alu DNA, centromeric DNA, SINE DNA, LINE DNA, or STR DNA. In some embodiments, the sequence of the second segments is selected from Table 3 and/or Table 4. In some embodiments, the targeting sequence is at least 80% complementary to the strand opposite to a sequence of nucleotides 5′ to a PAM sequence. In some embodiments, the target genomic sequence of interest is 5′ upstream of a PAM sequence. In some embodiments, the PAM sequence is specific for a CRISPR/Cas system protein selected from the group consisting of Cas9, Cpf1, Cas3, Cas8a-c, Cas10, Cse1, Csy1, Csn2, Cas4, Csm2, and Cm5. In some embodiments, the third segment comprises DNA encoding a gRNA stem-loop sequence. In some embodiments, the third segment comprises DNA encoding a gRNA stem-loop sequence. In some embodiments, the third segment encodes for a RNA comprising the sequence GUUUUAGAGCUAGAAAUAGCAAGUUAAAAUAAGGCUAGUCCGUUAUCAACUUGAAAAAGUGGCA CCGAGUCGGUGCUUUUUUU (SEQ ID NO: 1) or encodes for a RNA comprising the sequence GUUUUAGAGCUAUGCUGGAAACAGCAUAGCAAGUUAAAAUAAGGCUAGUCCGUUAUCAACUUGA AAAAGUGGCACCGAGUCGGUGCUUUUUUUC (SEQ ID NO: 2). In some embodiments, the nucleic acid-guided nuclease system protein is from a bacterial species. In some embodiments, the nucleic acid-guided nuclease system protein is from an archaea species. In some embodiments, the CRISPR/Cas system protein is a Type I, Type II, or Type III protein. In some embodiments, the CRISPR/Cas system protein is selected from the group consisting of Cas9, Cpf1, Cas3, Cas8a-c, Cas10, Cse1, Csy1, Csn2, Cas4, Csm2, Cm5, dCas9 and cas9 nickase. In some embodiments, the third segment comprises DNA encoding a Cas9-binding sequence.

In another aspect, the invention described herein provides a guide RNA comprising a first segment comprising a targeting sequence, wherein the size of the first segment is greater than 30 bp; and a second segment comprising a nucleic acid-guided nuclease system protein-binding sequence. In some embodiments, the nucleic acid-guided nuclease is a CRISPR/Cas system protein. In some embodiments, the gRNA comprises an adenine, a guanine, and a cytosine. In some embodiments, the gRNA further comprises a thymine. In some embodiments, the gRNA further comprises a uracil. In some embodiments, the size of the first RNA segment is between 30 and 250 bp. In some embodiments, the targeting sequence is directed at a mammalian genome, eukaryotic genome, prokaryotic genome, or viral genome. In some embodiments, the targeting sequence is directed at repetitive or abundant DNA. In some embodiments, the targeting sequence is directed at mitochondrial DNA, ribosomal DNA, Alu DNA, centromeric DNA, SINE DNA, LINE DNA, or STR DNA. In some embodiments, the first segment is at least 80% complementary to the target genomic sequence of interest. In some embodiments, the targeting sequence is at least 80% complementary to the strand opposite to a sequence of nucleotides 5′ to a PAM sequence. In some embodiments, the second segment comprises a gRNA stem-loop sequence. In some embodiments, the sequence of the second segment comprises GUUUUAGAGCUAGAAAUAGCAAGUUAAAAUAAGGCUAGUCCGUUAUCAACUUGAAAAAGUGGCA CCGAGUCGGUGCUUUUUUU (SEQ ID NO: 1) or comprises the sequence GUUUUAGAGCUAUGCUGGAAACAGCAUAGCAAGUUAAAAUAAGGCUAGUCCGUUAUCAACUUGA AAAAGUGGCACCGAGUCGGUGCUUUUUUUC (SEQ ID NO: 2). In some embodiments, the sequence of the third segment comprises a crRNA and a tracrRNA. In some embodiments, the nucleic acid-guided nuclease system protein is from a bacterial species. In some embodiments, the nucleic acid-guided nuclease system protein is from an archaea species. In some embodiments, the CRISPR/Cas system protein is a Type I, Type II, or Type III protein. In some embodiments, the CRISPR/Cas system protein is selected from the group consisting of Cas9, Cpf1, Cas3, Cas8a-c, Cas10, Cse1, Csy1, Csn2, Cas4, Csm2, Cm5, dCas9 and cas9 nickase. In some embodiments, the second segment is a Cas9-binding sequence.

In another aspect, the invention provides a complex comprising a nucleic acid-guided nuclease system protein and a comprising a first segment comprising a targeting sequence, wherein the size of the first segment is greater than 30 bp; and a second segment comprising a nucleic acid-guided nuclease system protein-binding sequence.

In another aspect, the invention described herein provides a method for depleting and partitioning of targeted sequences in a sample, enriching a sample for non-host nucleic acids, or serially depleting targeted nucleic acids in a sample comprising: providing nucleic acids extracted from a sample; and contacting the sample with a plurality of complexes comprising (i) any one of the collection of gRNAs provided herein; and (ii) nucleic acid-guided nuclease system proteins. In some embodiments, the nucleic acid-guided nuclease system proteins are CRISPR/Cas system proteins. In some embodiments, the CRISPR/Cas system proteins are Cas9 proteins.

In another aspect, the invention provides a method of making a collection of nucleic acids, each comprising a DNA encoding a targeting sequence ligated to a DNA encoding a nucleic acid-guided nuclease system protein-binding sequence, comprising: (a) providing double-stranded DNA molecules, each comprising a sequence of interest 5′ to a PAM sequence, and its reverse complementary sequence on the opposite strand; (b) performing an enzymatic digestion reaction on the double stranded DNA molecules, wherein cleavages are generated at the PAM sequence and/or its reverse complementary sequence on the opposite strand, but never completely remove the PAM sequence and/or its reverse complementary sequence on the opposite strand from the double stranded DNA; (c) ligating adapters comprising a recognition sequence to the resulting DNA molecules of step b; (d) contacting the DNA molecules of step c with an restriction enzyme that recognizes the recognition sequence of step c, whereby generating DNA fragments comprising blunt-ended double strand breaks immediately 5′ to the PAM sequence, whereby removing the PAM sequence and the adapter containing the enzyme recognition site; and (e) ligating the resulting double stranded DNA fragments of step d with a DNA encoding a nucleic acid-guided nuclease system protein-binding sequence, whereby generating a plurality of DNA fragments, each comprising a DNA encoding a targeting sequence ligated to a DNA encoding a nucleic acid-guided nuclease system protein-binding sequence. In some embodiments, the nucleic acid-guided nuclease is a CRISPR/Cas nucleic acid-guided nuclease system protein. In some embodiments, the starting DNA molecules of the collection further comprise a regulatory sequence upstream of the sequence of interest 5′ to the PAM sequence. In some embodiments, the regulatory sequence comprises a promoter. In some embodiments, the promoter comprises a T7, Sp6, or T3 sequence. In some embodiments, the double stranded DNA molecules are genomic DNA, intact DNA, or sheared DNA. In some embodiments, the genomic DNA is human, mouse, avian, fish, plant, insect, bacterial, or viral. In some embodiments, the DNA segments encoding a targeting sequence are at least 22 bp. In some embodiments, the DNA segments encoding a targeting sequence are 15-250 bp in size range. In some embodiments, the PAM sequence is AGG, CGG, or TGG. In some embodiments, the PAM sequence is specific for a CRISPR/Cas system protein selected from the group consisting of Cas9, Cpf1, Cas3, Cas8a-c, Cas10, Cse1, Csy1, Csn2, Cas4, Csm2, and Cm5. In some embodiments, step (b) further comprises (1) contacting the DNA molecules with an enzyme capable of creating a nick in a single strand at a CCD site, whereby generating a plurality of nicked double stranded DNA molecules, each comprising a sequence of interest followed by an HGG sequence, wherein the DNA molecules are nicked at the CCD sites; and (2) contacting the nicked double stranded DNA molecules with an endonuclease, whereby generating a plurality of double stranded DNA fragments, each comprising a sequence of interest followed by an HGG sequence wherein residual nucleotides from HGG and/or CCD sequences is (are) left behind. In some embodiments, step (d) further comprises PCR amplification of the adaptor-ligated DNA fragments from step (c) before cutting with the restriction enzyme recognizing the recognition sequence of step (c), wherein after PCR, the recognition sequence is positioned 3′ of the PAM sequence, and a regulatory sequence is positioned at the 5′ distal end of the PAM sequence. In some embodiments, the enzymatic reaction of step (b) comprises the use of a Nt.CviPII enzyme, and a T7 Endonuclease I enzyme. In some embodiments, step (c) further comprises a blunt-end reaction with a T4 DNA Polymerase, if the adapter to be ligated does not comprise an overhang. In some embodiments, the adapter of step (c) is either (1) double stranded, comprising a restriction enzyme recognition sequence in one strand, and a regulatory sequence in the other strand, if the adapter is Y-shaped and comprises an overhang; or (2) has a palindromic enzyme recognition sequence in both strands, if the adapter is not Y-shaped. In some embodiments, the restriction enzyme of step (d) is MlyI. In some embodiments, the restriction enzyme of step (d) is BaeI. In some embodiments, step (d) further comprises contacting the DNA molecules with an XhoI enzyme. In some embodiments, in step (e) the DNA encoding a nucleic acid-guided nuclease system-protein binding sequence encodes for a RNA comprising the sequence GUUUUAGAGCUAGAAAUAGCAAGUUAAAAUAAGGCUAGUCCGUUAUCAACUUGAAAAAGUGGCA CCGAGUCGGUGCUUUUUUU (SEQ ID NO: 1) or encodes for a RNA comprising the sequence GUUUUAGAGCUAUGCUGGAAACAGCAUAGCAAGUUAAAAUAAGGCUAGUCCGUUAUCAACUUGA AAAAGUGGCACCGAGUCGGUGCUUUUUUUC (SEQ ID NO: 2). In some embodiments, the targeted sequences of interest are spaced every 10,000 bp or less across the genome of an organism.

In another aspect, the invention provides a method of making a collection of nucleic acids, each comprising a DNA encoding a targeting sequence ligated to a DNA encoding a nucleic acid-guided nuclease system protein-binding sequence, comprising: (a) providing a plurality of double stranded DNA molecules, each comprising a sequence of interest, an NGG site, and its complement CCN site; (b) contacting the molecules with an enzyme capable of creating a nick in a single strand at a CCN site, whereby generating a plurality of nicked double stranded DNA molecules, each comprising a sequence of interest 5′ to the NGG site, wherein the DNA molecules are nicked at the CCD sites; (c) contacting the nicked double stranded DNA molecules with an endonuclease, whereby generating a plurality of double stranded DNA fragments, each comprising a sequence of interest, wherein the fragments comprise an terminal overhang; (d) contacting the double stranded DNA fragments with an enzyme without 5′ to 3′ exonuclease activity to blunt end the double stranded DNA fragments, whereby generating a plurality of blunt ended double stranded fragments, each comprising a sequence of interest; (e) contacting the blunt ended double stranded fragments of step d with an enzyme that cleaves the terminal NGG site; and (f) ligating the resulting double stranded DNA fragments of step e with a DNA encoding a nucleic acid-guided nuclease system-protein binding sequence, whereby generating a plurality of DNA fragments, each comprising a targeting sequence ligated to a DNA encoding a nucleic acid-guided nuclease system protein-binding sequence. In some embodiments, the nucleic acid-guided nuclease is a CRISPR/Cas system protein. In some embodiments, the plurality of double stranded DNA molecules have a regulatory sequence 5′ upstream of the NGG sites. In some embodiments, the regulatory sequence comprises a T7, SP6, or T3 sequence. In some embodiments, the NGG site comprises AGG, CGG, or TGG, and the CCN site comprises CCT, CCG, or CCA. In some embodiments, the plurality of double stranded DNA molecules, each comprising a sequence of interest comprise sheared fragments of genomic DNA. In some embodiments, the genomic DNA is mammalian, prokaryotic, eukaryotic, avian, bacterial or viral. In some embodiments, the plurality of double stranded DNA molecules in step (a) are at least 500 bp. In some embodiments, the enzyme in step b is a Nt.CviPII enzyme. In some embodiments, the enzyme in step c is a T7 Endonuclease I. In some embodiments, the enzyme in step d is a T4 DNA Polymerase. In some embodiments, in step f the DNA encoding a nucleic acid-guided nuclease system-protein binding sequence encodes for a RNA comprising the sequence GUUUUAGAGCUAGAAAUAGCAAGUUAAAAUAAGGCUAGUCCGUUAUCAACUUGAAAAAGUGGCA CCGAGUCGGUGCUUUUUUU (SEQ ID NO: 1) or encodes for a RNA comprising the sequence GUUUUAGAGCUAUGCUGGAAACAGCAUAGCAAGUUAAAAUAAGGCUAGUCCGUUAUCAACUUGA AAAAGUGGCACCGAGUCGGUGCUUUUUUUC (SEQ ID NO: 2). In some embodiments, the step e additionally comprises ligating adaptors carrying a MlyI recognition site and digesting with MlyI enzyme. In some embodiments, the sequence of interest is spaced every 10,000 bp or less across the genome.

In another aspect, the invention provides a method of making a collection of nucleic acids, each comprising a DNA encoding a targeting sequence and a DNA encoding a nucleic acid-guided nuclease system protein-binding sequence, comprising: (a) providing genomic DNA comprising a plurality of sequences of interest, comprising NGG and CCN sites; (b) contacting the genomic DNA with an enzyme capable of creating nicks in the genomic DNA, whereby generating nicked genomic DNA, nicked at CCN sites; (c) contacting the nicked genomic DNA with an endonuclease, whereby generating double stranded DNA fragments, with an overhang; (d) ligating the DNA with overhangs from step c to a Y-shaped adapter, thereby introducing a restriction enzyme recognition sequence only at 3′ of the NGG site and a regulatory sequence 5′ of the sequence of interest; (e) contacting the product from step d with an enzyme that cleaves away the NGG site together with the adaptor carrying the enzyme recognition sequence; and (f) ligating the resulting double stranded DNA fragments of step e with a DNA encoding a nucleic acid-guided nuclease system protein-binding sequence, whereby generating a plurality of DNA fragments, each comprising a sequence of interest ligated to a DNA encoding a nucleic acid-guided nuclease system protein-binding sequence. In some embodiments, the nucleic acid-guided nuclease is a CRISPR/Cas system protein. In some embodiments, the NGG site comprises AGG, CGG, or TGG, and CCN site comprises CCT, CCG, or CCA. In some embodiments, the regulatory sequence comprises a promoter sequence. In some embodiments, the promoter sequence comprises a T7, SP6, or T3 sequence. In some embodiments, the DNA fragments are sheared fragments of genomic DNA.

In some embodiments, the genomic DNA is mammalian, prokaryotic, eukaryotic, or viral. In some embodiments, the fragments are at least 200 bp. In some embodiments, the enzyme in step b is a Nt.CviPII enzyme. In some embodiments, the enzyme in step c is a T7 Endonuclease I. In some embodiments, step d further comprises PCR amplification of the adaptor-ligated DNA. In some embodiments, in step f, the DNA encoding nucleic acid-guided nuclease system protein-binding sequence encodes for a RNA comprising the sequence GUUUUAGAGCUAGAAAUAGCAAGUUAAAAUAAGGCUAGUCCGUUAUCAACUUGAAAAAGUGGCA CCGAGUCGGUGCUUUUUUU (SEQ ID NO: 1) or encodes for a RNA comprising the sequence GUUUUAGAGCUAUGCUGGAAACAGCAUAGCAAGUUAAAAUAAGGCUAGUCCGUUAUCAACUUGA AAAAGUGGCACCGAGUCGGUGCUUUUUUUC (SEQ ID NO: 2). In some embodiments, the enzyme removing NGG site in step e is MlyI. In some embodiments, the target of interest of the collection is spaced every 10,000 bp or less across the genome.

In another aspect, the invention provides kits and/or reagents useful for performing a method of making a collection of nucleic acids, each comprising a DNA encoding a targeting sequence ligated to a DNA encoding a nucleic acid-guided nuclease system protein-binding sequence, as described in the embodiments herein.

In another aspect, the invention described herein provides kit comprising a collection of nucleic acids, a plurality of the nucleic acids in the collection comprising: a first segment comprising a regulatory region; a second segment encoding a targeting sequence; and a third segment encoding a CRISPR/Cas system protein-binding sequence, wherein at least 10% of the nucleic acids in the collection vary in size.

In another aspect, the invention described herein provides a kit comprising a collection of nucleic acids, a plurality of the nucleic acids in the collection comprising: a first segment comprising a regulatory region; a second segment encoding a targeting sequence, wherein the size of the second segment is greater than 21 bp; and a third segment encoding a CRISPR/Cas system protein-binding sequence.

In another aspect, the invention described herein provides a kit comprising a collection of guide RNAs comprising a first RNA segment a targeting sequence; and a second RNA segment comprising a CRISPR/Cas system protein-binding sequence, wherein at least 10% of the gRNAs in the collection vary in size.

In another aspect, the invention described herein provides a method of making a collection of guide nucleic acids, comprising: a. obtaining abundant cells in a source sample; b. collecting nucleic acids from said abundant cells; and c. preparing a collection of guide nucleic acids (gNAs) from said nucleic acids. In some embodiments, said abundant cells comprise cells from one or more most abundant bacterial species in said source sample. In some embodiments, said abundant cells comprise cells from more than one species. In some embodiments, said abundant cells comprise human cells. In some embodiments, said abundant cells comprise animal cells. In some embodiments, said abundant cells comprise plant cells. In some embodiments, said abundant cells comprise bacterial cells. In some embodiments, the method further comprises contacting nucleic acid-guided nucleases with said library of gNAs to form nucleic acid-guided nuclease-gNA complexes. In some embodiments, the method further comprises using said nucleic acid-guided nuclease-gNA complexes to cleave target nucleic acids at target sites, wherein said gNAs are complementary to said target sites. In some embodiments, said target nucleic acids are from said source sample. In some embodiments, a species of said target nucleic acids is the same as a species of said source sample. In some embodiments, said species of said target nucleic acids and said species of said source sample is human. In some embodiments, said species of said target nucleic acids and said species of said source sample is animal. In some embodiments, said species of said target nucleic acids and said species of said source sample is plant.

In another aspect, the invention described herein provides a method of making a collection of nucleic acids, each comprising a targeting sequence, comprising: a. obtaining source DNA; b. nicking said source DNA with a nicking enzyme at nicking enzyme recognition sites, thereby producing double-stranded breaks at proximal nicks; and c. repairing overhangs of said double-stranded breaks, thereby producing a double-stranded fragment comprising (i) a targeting sequence and (ii) said nicking enzyme recognition site. In another aspect, the invention described herein provides a method of making a collection of nucleic acids, each comprising a targeting sequence, comprising: a. obtaining source DNA; b. nicking said source DNA with a nicking enzyme at nicking enzyme recognition sites, thereby producing a nick; and c. synthesizing a new strand from said nick, thereby producing a single-stranded fragment of said source DNA comprising a targeting sequence. In some embodiments, the method further comprises producing a double-stranded fragment comprising said targeting sequence from said single-stranded fragment. In some embodiments, said producing said double-stranded fragment comprises random priming and extension. In some embodiments, said random priming is conducted with a primer comprising a random n-mer region and a promoter region. In some embodiments, said random n-mer region is a random hexamer region. In some embodiments, said random n-mer region is a random octamer region. In some embodiments, said promoter region is a T7 promoter region. In some embodiments, the method further comprises ligating a nuclease recognition site nucleic acid comprising a nuclease recognition site to said double-stranded fragment. In some embodiments, said nuclease recognition site corresponds to a nuclease that cuts at a distance from said nuclease recognition site equal to the length of said nicking enzyme recognition sites. In some embodiments, said nuclease recognition site is a MlyI recognition site. In some embodiments, said nuclease recognition site is a BaeI recognition site. In some embodiments, the method further comprises digesting said double-stranded fragment with said nuclease, thereby removing said nicking enzyme recognition site from said double-stranded fragment. In some embodiments, the method further comprises ligating said double-stranded fragment to a nucleic acid-guided nuclease system protein recognition site nucleic acid comprising a nucleic acid-guided nuclease system protein recognition site. In some embodiments, said nucleic acid-guided nuclease system protein recognition site comprises a guide RNA stem-loop sequence. In some embodiments, said nuclease recognition site corresponds to a nuclease that cuts at a distance from said nuclease recognition site equal to a length of said targeting sequence. In some embodiments, said length of said targeting sequence is 20 base pairs. In some embodiments, said nuclease recognition site is a MmeI recognition site. In some embodiments, the method further comprises digesting said double-stranded fragment with said nuclease. In some embodiments, said nuclease recognition site corresponds to a nuclease that cuts at a distance from said nuclease recognition site equal to a length of said targeting sequence plus a length of said nicking enzyme recognition sites. In some embodiments, said length of said targeting sequence plus a length of said nicking enzyme recognition sites is 23 base pairs. In some embodiments, said nuclease recognition site is a EcoP15I recognition site. In some embodiments, the method further comprises digesting said double-stranded fragment with said nuclease. In some embodiments, the method further comprises ligating said double-stranded fragment to a nucleic acid-guided nuclease system protein recognition site nucleic acid comprising a nucleic acid-guided nuclease system protein recognition site. In some embodiments, said nucleic acid-guided nuclease system protein recognition site comprises a guide RNA stem-loop sequence.

In another aspect, the invention described herein provides a kit comprising all essential reagents and instructions for carrying out the methods of aspects of the invention described herein.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 illustrates an exemplary scheme for producing a collection of gRNAs (a gRNA library) from genomic DNA.

FIG. 2 illustrates another exemplary scheme for producing a collection of gRNAs (a gRNA library) from genomic DNA.

FIG. 3 illustrates an exemplary scheme for nicking of DNA and subsequent treatment with polymerase to generate blunt ends.

FIG. 4 illustrates an exemplary scheme for sequential production of a library of gNAs using three adapters.

FIG. 5 illustrates an exemplary scheme for sequential production of a library of gNAs using one adapter and one oligo.

FIG. 6 illustrates an exemplary scheme for generation of a large pool of DNA fragments with blunt ends using Nicking Enzyme Mediated DNA Amplification (NEMDA).

FIG. 7 illustrates an exemplary scheme for generation of a large pool of gNAs using Nicking Enzyme Mediated DNA Amplification (NEMDA).

DETAILED DESCRIPTION OF THE INVENTION

There is a need in the art for a scalable, low-cost approach to generate large numbers of diverse guide nucleic acids (gNAs) (e.g., gRNAs, gDNAs) for a variety of downstream applications.

Unless defined otherwise herein, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. Although any methods and materials similar or equivalent to those described herein can be used in the practice or testing of the present invention, the preferred methods and materials are described.

Numeric ranges are inclusive of the numbers defining the range.

For purposes of interpreting this specification, the following definitions will apply and whenever appropriate, terms used in the singular will also include the plural and vice versa. In the event that any definition set forth below conflicts with any document incorporated herein by reference, the definition set forth shall control.

As used herein, the singular form “a”, “an”, and “the” includes plural references unless indicated otherwise.

It is understood that aspects and embodiments of the invention described herein include “comprising,” “consisting,” and “consisting essentially of” aspects and embodiments.

The term “about” as used herein refers to the usual error range for the respective value readily known to the skilled person in this technical field. Reference to “about” a value or parameter herein includes (and describes) embodiments that are directed to that value or parameter per se.

The term “nucleic acid,” as used herein, refers to a molecule comprising one or more nucleic acid subunits. A nucleic acid can include one or more subunits selected from adenosine (A), cytosine (C), guanine (G), thymine (T) and uracil (U), and modified versions of the same. A nucleic acid comprises deoxyribonucleic acid (DNA), ribonucleic acid (RNA), combinations, or derivatives thereof. A nucleic acid may be single-stranded and/or double-stranded.

The nucleic acids comprise “nucleotides”, which, as used herein, is intended to include those moieties that contain purine and pyrimidine bases, and modified versions of the same. Such modifications include methylated purines or pyrimidines, acylated purines or pyrimidines, alkylated riboses or other heterocycles. In addition, the term “nucleotide” or “polynucleotide” includes those moieties that contain hapten or fluorescent labels and may contain not only conventional ribose and deoxyribose sugars, but other sugars as well. Modified nucleosides, nucleotides or polynucleotides also include modifications on the sugar moiety, e.g., wherein one or more of the hydroxyl groups are replaced with halogen atoms or aliphatic groups, or are functionalized as ethers, amines, or the like.

The term “nucleic acids” and “polynucleotides” are used interchangeably herein. Polynucleotide is used to describe a nucleic acid polymer of any length, e.g., greater than about 2 bases, greater than about 10 bases, greater than about 100 bases, greater than about 500 bases, greater than 1000 bases, up to about 10,000 or more bases composed of nucleotides, e.g., deoxyribonucleotides or ribonucleotides, and may be produced enzymatically or synthetically (e.g., PNA as described in U.S. Pat. No. 5,948,902 and the references cited therein) which can hybridize with naturally occurring nucleic acids in a sequence specific manner analogous to that of two naturally occurring nucleic acids, e.g., can participate in Watson-Crick base pairing interactions. Naturally-occurring nucleotides include guanine, cytosine, adenine and thymine (G, C, A and T, respectively). DNA and RNA have a deoxyribose and ribose sugar backbones, respectively, whereas PNA's backbone is composed of repeating N-(2-aminoethyl)-glycine units linked by peptide bonds. In PNA various purine and pyrimidine bases are linked to the backbone by methylene carbonyl bonds. A locked nucleic acid (LNA), often referred to as inaccessible RNA, is a modified RNA nucleotide. The ribose moiety of an LNA nucleotide is modified with an extra bridge connecting the 2′ oxygen and 4′ carbon. The bridge “locks” the ribose in the 3′-endo (North) conformation, which is often found in the A-form duplexes. LNA nucleotides can be mixed with DNA or RNA residues in the oligonucleotide whenever desired. The term “unstructured nucleic acid,” or “UNA,” is a nucleic acid containing non-natural nucleotides that bind to each other with reduced stability. For example, an unstructured nucleic acid may contain a G′ residue and a C′ residue, where these residues correspond to non-naturally occurring forms, i.e., analogs, of G and C that base pair with each other with reduced stability, but retain an ability to base pair with naturally occurring C and G residues, respectively. Unstructured nucleic acid is described in US20050233340, which is incorporated by reference herein for disclosure of UNA.

The term “oligonucleotide” as used herein denotes a single-stranded multimer of nucleotides.

Unless otherwise indicated, nucleic acids are written left to right in 5′ to 3′ orientation; amino acid sequences are written left to right in amino to carboxy orientation, respectively.

The term “cleaving,” as used herein, refers to a reaction that breaks the phosphodiester bonds between two adjacent nucleotides in both strands of a double-stranded DNA molecule, thereby resulting in a double-stranded break in the DNA molecule.

The term “nicking” as used herein, refers to a reaction that breaks the phosphodiester bond between two adjacent nucleotides in only one strand of a double-stranded DNA molecule, thereby resulting in a break in one strand of the DNA molecule.

The term “cleavage site, as used herein, refers to the site at which a double-stranded DNA molecule has been cleaved.

The “nucleic acid-guided nuclease-gNA complex” refers to a complex comprising a nucleic acid-guided nuclease protein and a guide nucleic acid (gNA, for example a gRNA or a gDNA). For example the “Cas9-gRNA complex” refers to a complex comprising a Cas9 protein and a guide RNA (gRNA). The nucleic acid-guided nuclease may be any type of nucleic acid-guided nuclease, including but not limited to wild type nucleic acid-guided nuclease, a catalytically dead nucleic acid-guided nuclease, or a nucleic acid-guided nuclease-nickase.

The term “nucleic acid-guided nuclease-associated guide NA” refers to a guide nucleic acid (guide NA). The nucleic acid-guided nuclease-associated guide NA may exist as an isolated nucleic acid, or as part of a nucleic acid-guided nuclease-gNA complex, for example a Cas9-gRNA complex.

The terms “capture” and “enrichment” are used interchangeably herein, and refer to the process of selectively isolating a nucleic acid region containing: sequences of interest, targeted sites of interest, sequences not of interest, or targeted sites not of interest.

The term “hybridization” refers to the process by which a strand of nucleic acid joins with a complementary strand through base pairing as known in the art. A nucleic acid is considered to be “selectively hybridizable” to a reference nucleic acid sequence if the two sequences specifically hybridize to one another under moderate to high stringency hybridization and wash conditions. Moderate and high stringency hybridization conditions are known (see, e.g., Ausubel, et al., Short Protocols in Molecular Biology, 3rd ed., Wiley & Sons 1995 and Sambrook et al., Molecular Cloning: A Laboratory Manual, Third Edition, 2001 Cold Spring Harbor, N.Y.). One example of high stringency conditions includes hybridization at about 42° C. in 50% formamide, 5×SSC, 5×Denhardt's solution, 0.5% SDS and 100 μg/ml denatured carrier DNA followed by washing two times in 2×SSC and 0.5% SDS at room temperature and two additional times in 0.1×SSC and 0.5% SDS at 42° C.

The term “duplex,” or “duplexed,” as used herein, describes two complementary polynucleotides that are base-paired, i.e., hybridized together.

The term “amplifying” as used herein refers to generating one or more copies of a target nucleic acid, using the target nucleic acid as a template.

The term “genomic region,” as used herein, refers to a region of a genome, e.g., an animal or plant genome such as the genome of a human, monkey, rat, fish or insect or plant. In certain cases, an oligonucleotide used in the method described herein may be designed using a reference genomic region, i.e., a genomic region of known nucleotide sequence, e.g., a chromosomal region whose sequence is deposited at NCBI's Genbank database or other databases, for example.

The term “genomic sequence,” as used herein, refers to a sequence that occurs in a genome. Because RNAs are transcribed from a genome, this term encompasses sequence that exist in the nuclear genome of an organism, as well as sequences that are present in a cDNA copy of an RNA (e.g., an mRNA) transcribed from such a genome.

The term “genomic fragment,” as used herein, refers to a region of a genome, e.g., an animal or plant genome such as the genome of a human, monkey, rat, fish or insect or plant. A genomic fragment may be an entire chromosome, or a fragment of a chromosome. A genomic fragment may be adapter ligated (in which case it has an adapter ligated to one or both ends of the fragment, or to at least the 5′ end of a molecule), or may not be adapter ligated.

In certain cases, an oligonucleotide used in the method described herein may be designed using a reference genomic region, i.e., a genomic region of known nucleotide sequence, e.g., a chromosomal region whose sequence is deposited at NCBI's Genbank database or other databases, for example Such an oligonucleotide may be employed in an assay that uses a sample containing a test genome, where the test genome contains a binding site for the oligonucleotide.

The term “ligating,” as used herein, refers to the enzymatically catalyzed joining of the terminal nucleotide at the 5′ end of a first DNA molecule to the terminal nucleotide at the 3′ end of a second DNA molecule.

If two nucleic acids are “complementary,” each base of one of the nucleic acids base pairs with corresponding nucleotides in the other nucleic acid. The term “complementary” and “perfectly complementary” are used synonymously herein.

The term “separating,” as used herein, refers to physical separation of two elements (e.g., by size or affinity, etc.) as well as degradation of one element, leaving the other intact. For example, size exclusion can be employed to separate nucleic acids, including cleaved targeted sequences.

In a cell, DNA usually exists in a double-stranded form, and as such, has two complementary strands of nucleic acid referred to herein as the “top” and “bottom” strands. In certain cases, complementary strands of a chromosomal region may be referred to as “plus” and “minus” strands, the “first” and “second” strands, the “coding” and “noncoding” strands, the “Watson” and “Crick” strands or the “sense” and “antisense” strands. The assignment of a strand as being a top or bottom strand is arbitrary and does not imply any particular orientation, function or structure. Until they become covalently linked, the first and second strands are distinct molecules. For ease of description, the “top” and “bottom” strands of a double-stranded nucleic acid in which the top and bottom strands have been covalently linked will still be described as the “top” and “bottom” strands. In other words, for the purposes of this disclosure, the top and bottom strands of a double-stranded DNA do not need to be separated molecules. The nucleotide sequences of the first strand of several exemplary mammalian chromosomal regions (e.g., BACs, assemblies, chromosomes, etc.) is known, and may be found in NCBI's Genbank database, for example.

The term “top strand,” as used herein, refers to either strand of a nucleic acid but not both strands of a nucleic acid. When an oligonucleotide or a primer binds or anneals “only to a top strand,” it binds to only one strand but not the other. The term “bottom strand,” as used herein, refers to the strand that is complementary to the “top strand.” When an oligonucleotide binds or anneals “only to one strand,” it binds to only one strand, e.g., the first or second strand, but not the other strand. If an oligonucleotide binds or anneals to both strands of a double-stranded DNA, the oligonucleotide may have two regions, a first region that hybridizes with the top strand of the double-stranded DNA, and a second region that hybridizes with the bottom strand of the double-stranded DNA.

The term “double-stranded DNA molecule” refers to both double-stranded DNA molecules in which the top and bottom strands are not covalently linked, as well as double-stranded DNA molecules in which the top and bottom stands are covalently linked. The top and bottom strands of a double-stranded DNA are base paired with one other by Watson-Crick interactions.

The term “denaturing,” as used herein, refers to the separation of at least a portion of the base pairs of a nucleic acid duplex by placing the duplex in suitable denaturing conditions. Denaturing conditions are well known in the art. In one embodiment, in order to denature a nucleic acid duplex, the duplex may be exposed to a temperature that is above the T_(m) of the duplex, thereby releasing one strand of the duplex from the other. In certain embodiments, a nucleic acid may be denatured by exposing it to a temperature of at least 90° C. for a suitable amount of time (e.g., at least 30 seconds, up to 30 mins). In certain embodiments, fully denaturing conditions may be used to completely separate the base pairs of the duplex. In other embodiments, partially denaturing conditions (e.g., with a lower temperature than fully denaturing conditions) may be used to separate the base pairs of certain parts of the duplex (e.g., regions enriched for A-T base pairs may separate while regions enriched for G-C base pairs may remain paired). Nucleic acid may also be denatured chemically (e.g., using urea or NaOH).

The term “genotyping,” as used herein, refers to any type of analysis of a nucleic acid sequence, and includes sequencing, polymorphism (SNP) analysis, and analysis to identify rearrangements.

The term “sequencing,” as used herein, refers to a method by which the identity of consecutive nucleotides of a polynucleotide are obtained.

The term “next-generation sequencing” refers to the so-called parallelized sequencing-by-synthesis or sequencing-by-ligation platforms, for example, those currently employed by Illumina, Life Technologies, and Roche, etc. Next-generation sequencing methods may also include nanopore sequencing methods or electronic-detection based methods such as Ion Torrent technology commercialized by Life Technologies.

The term “complementary DNA” or cDNA refers to a double-stranded DNA sample that was produced from an RNA sample by reverse transcription of RNA (using primers such as random hexamers or oligo-dT primers) followed by second-strand synthesis by digestion of the RNA with RNaseH and synthesis by DNA polymerase.

The term “RNA promoter adapter” is an adapter that contains a promoter for a bacteriophage RNA polymerase, e.g., the RNA polymerase from bacteriophage T3, T7, SP6 or the like.

Other definitions of terms may appear throughout the specification.

For any of the structural and functional characteristics described herein, methods of determining these characteristics are known in the art.

Guide Nucleic Acids (gNAs)

Provided herein are guide nucleic acids (gNAs) derivable from any nucleic acid source. The gNAs can be guide RNAs (gRNAs) or guide DNAs (gDNAs). The nucleic acid source can be DNA or RNA. Provided herein are methods to generate gNAs from any source nucleic acid, including DNA from a single organism, or mixtures of DNA from multiple organisms, or mixtures of DNA from multiple species, or DNA from clinical samples, or DNA from forensic samples, or DNA from environmental samples, or DNA from metagenomic DNA samples (for example a sample that contains more than one species of organism). Examples of any source DNA include, but are not limited to any genome, any genome fragment, cDNA, synthetic DNA, or a DNA collection (e.g. a SNP collection, DNA libraries). The gNAs provided herein can be used for genome-wide applications.

In some embodiments, the gNAs are derived from genomic sequences (e.g., genomic DNA). In some embodiments, the gNAs are derived from mammalian genomic sequences. In some embodiments, the gNAs are derived from eukaryotic genomic sequences. In some embodiments, the gNAs are derived from prokaryotic genomic sequences. In some embodiments, the gNAs are derived from viral genomic sequences. In some embodiments, the gNAs are derived from bacterial genomic sequences. In some embodiments, the gNAs are derived from plant genomic sequences. In some embodiments, the gNAs are derived from microbial genomic sequences. In some embodiments, the gNAs are derived from genomic sequences from a parasite, for example a eukaryotic parasite.

In some embodiments, the gNAs are derived from repetitive DNA. In some embodiments, the gNAs are derived from abundant DNA. In some embodiments, the gNAs are derived from mitochondrial DNA. In some embodiments, the gNAs are derived from ribosomal DNA. In some embodiments, the gNAs are derived from centromeric DNA. In some embodiments, the gNAs are derived from DNA comprising Alu elements (Alu DNA). In some embodiments, the gNAs are derived from DNA comprising long interspersed nuclear elements (LINE DNA). In some embodiments, the gNAs are derived from DNA comprising short interspersed nuclear elements (SINE DNA). In some embodiments the abundant DNA comprises ribosomal DNA. In some embodiments, the abundant DNA comprises host DNA (e.g., host genomic DNA or all host DNA). In an example, the gNAs can be derived from host DNA (e.g., human, animal, plant) for the depletion of host DNA to allow for easier analysis of other DNA that is present (e.g., bacterial, viral, or other metagenomic DNA). In another example, the gNAs can be derived from the one or more most abundant types (e.g., species) in a mixed sample, such as the one or more most abundant bacteria species in a metagenomic sample. The one or more most abundant types (e.g., species) can comprise the two, three, four, five, six, seven, eight, nine, ten, or more than ten most abundant types (e.g., species). The most abundant types can be the most abundant kingdoms, phyla or divisions, classes, orders, families, genuses, species, or other classifications. The most abundant types can be the most abundant cell types, such as epithelial cells, bone cells, muscle cells, blood cells, adipose cells, or other cell types. The most abundant types can be non-cancerous cells. The most abundant types can be cancerous cells. The most abundant types can be animal, human, plant, fungal, bacterial, or viral. gNAs can be derived from both a host and the one or more most abundant non-host types (e.g., species) in a sample, such as from both human DNA and the DNA of the one or more most abundant bacterial species. In some embodiments, the abundant DNA comprises DNA from the more abundant or most abundant cells in a sample. For example, for a specific sample, the highly abundant cells can be extracted and their DNA can be used to produce gNAs; these gNAs can be used to produce depletion library and applied to original sample to enable or enhance sequencing or detection of low abundance targets.

In some embodiments, the gNAs are derived from DNA comprising short terminal repeats (STRs).

In some embodiments, the gNAs are derived from a genomic fragment, comprising a region of the genome, or the whole genome itself. In one embodiment, the genome is a DNA genome. In another embodiment, the genome is a RNA genome.

In some embodiments, the gNAs are derived from a eukaryotic or prokaryotic organism; from a mammalian organism or a non-mammalian organism; from an animal or a plant; from a bacteria or virus; from an animal parasite; from a pathogen.

In some embodiments, the gNAs are derived from any mammalian organism. In one embodiment the mammal is a human. In another embodiment the mammal is a livestock animal, for example a horse, a sheep, a cow, a pig, or a donkey. In another embodiment, a mammalian organism is a domestic pet, for example a cat, a dog, a gerbil, a mouse, a rat. In another embodiment the mammal is a type of a monkey.

In some embodiments, the gNAs are derived from any bird or avian organism. An avian organism includes but is not limited to chicken, turkey, duck and goose.

In some embodiments, the gNAs are derived from a plant. In one embodiment, the plant is rice, maize, wheat, rose, grape, coffee, fruit, tomato, potato, or cotton.

In some embodiments, the gNAs are derived from a species of bacteria. In one embodiment, the bacteria are tuberculosis-causing bacteria.

In some embodiments, the gNAs are derived from a virus.

In some embodiments, the gNAs are derived from a species of fungi.

In some embodiments, the gNAs are derived from a species of algae.

In some embodiments, the gNAs are derived from any mammalian parasite.

In some embodiments, the gNAs are derived from any mammalian parasite. In one embodiment, the parasite is a worm. In another embodiment, the parasite is a malaria-causing parasite. In another embodiment, the parasite is a Leishmaniasis-causing parasite. In another embodiment, the parasite is an amoeba.

In some embodiments, the gNAs are derived from a nucleic acid target. Contemplated targets include, but are not limited to, pathogens; single nucleotide polymorphisms (SNPs), insertions, deletions, tandem repeats, or translocations; human SNPs or STRs; potential toxins; or animals, fungi, and plants. In some embodiments, the gRNAs are derived from pathogens, and are pathogen-specific gNAs.

In some embodiments, a guide NA of the invention comprises a first NA segment comprising a targeting sequence, wherein the targeting sequence is 15-250 bp; and a second NA segment comprising a nucleic acid guided nuclease system (e.g., CRISPR/Cas system) protein-binding sequence. In some embodiments, the targeting sequence is greater than 21 bp, greater than 22 bp, greater than 23 bp, greater than 24 bp, greater than 25 bp, greater than 26 bp, greater than 27 bp, greater than 28 bp, greater than 29 bp, greater than 30 bp, greater than 40 bp, greater than 50 bp, greater than 60 bp, greater than 70 bp, greater than 80 bp, greater than 90 bp, greater than 100 bp, greater than 110 bp, greater than 120 bp, greater than 130 bp, greater than 140 bp, or even greater than 150 bp. In an exemplary embodiment, the targeting sequence is greater than 30 bp. In some embodiments, the targeting sequences of the present invention range in size from 30-50 bp. In some embodiments, targeting sequences of the present invention range in size from 30-75 bp. In some embodiments, targeting sequences of the present invention range in size from 30-100 bp. For example, a targeting sequence can be at least 15 bp, 20 bp, 25 bp, 30 bp, 35 bp, 40 bp, 45 bp, 50 bp, 55 bp, 60 bp, 65 bp, 70 bp, 75 bp, 80 bp, 85 bp, 90 bp, 95 bp, 100 bp, 110 bp, 120 bp, 130 bp, 140 bp, 150 bp, 160 bp, 170 bp, 180 bp, 190 bp, 200 bp, 210 bp, 220 bp, 230 bp, 240 bp, or 250 bp. In specific embodiments, the targeting sequence is at least 22 bp. In specific embodiments, the targeting sequence is at least 30 bp.

In some embodiments, target-specific gNAs can comprise a nucleic acid sequence that is complementary to a region on the opposite strand of the targeted nucleic acid sequence 5′ to a PAM sequence, which can be recognized by a nucleic acid-guided nuclease system (e.g., CRISPR/Cas system) protein. In some embodiments the targeted nucleic acid sequence is immediately 5′ to a PAM sequence. In specific embodiments, the nucleic acid sequence of the gNA that is complementary to a region in a target nucleic acid is 15-250 bp. In specific embodiments, the nucleic acid sequence of the gNA that is complementary to a region in a target nucleic acid is 22, 23, 24, 25, 30, 35, 40, 45, 50, 60, 70, 75, 80, 90, or 100 bp.

In some particular embodiments, the targeting sequence is not 20 bp. In some particular embodiments, the targeting sequence is not 21 bp.

In some embodiments, the gNAs comprise any purines or pyrimidines (and/or modified versions of the same). In some embodiments, the gNAs comprise adenine, uracil, guanine, and cytosine (and/or modified versions of the same). In some embodiments, the gNAs comprise adenine, thymine, guanine, and cytosine (and/or modified versions of the same). In some embodiments, the gNAs comprise adenine, thymine, guanine, cytosine and uracil (and/or modified versions of the same).

In some embodiments, the gNAs comprise a label, are attached to a label, or are capable of being labeled. In some embodiments, the gNA comprises is a moiety that is further capable of being attached to a label. A label includes, but is not limited to, enzyme, an enzyme substrate, an antibody, an antigen binding fragment, a peptide, a chromophore, a lumiphore, a fluorophore, a chromogen, a hapten, an antigen, a radioactive isotope, a magnetic particle, a metal nanoparticle, a redox active marker group (capable of undergoing a redox reaction), an aptamer, one member of a binding pair, a member of a FRET pair (either a donor or acceptor fluorophore), and combinations thereof.

In some embodiments, the gNAs are attached to a substrate. The substrate can be made of glass, plastic, silicon, silica-based materials, functionalized polystyrene, functionalized polyethyleneglycol, functionalized organic polymers, nitrocellulose or nylon membranes, paper, cotton, and materials suitable for synthesis. Substrates need not be flat. In some embodiments, the substrate is a 2-dimensional array. In some embodiments, the 2-dimensional array is flat. In some embodiments, the 2-dimensional array is not flat, for example, the array is a wave-like array. Substrates include any type of shape including spherical shapes (e.g., beads). Materials attached to substrates may be attached to any portion of the substrates (e.g., may be attached to an interior portion of a porous substrates material). In some embodiments, the substrate is a 3-dimensional array, for example, a microsphere. In some embodiments, the microsphere is magnetic. In some embodiments, the microsphere is glass. In some embodiments, the microsphere is made of polystyrene. In some embodiments, the microsphere is silica-based. In some embodiments, the substrate is an array with interior surface, for example, is a straw, tube, capillary, cylindrical, or microfluidic chamber array. In some embodiments, the substrate comprises multiple straws, capillaries, tubes, cylinders, or chambers.

Nucleic Acids Encoding gNAs

Also provided herein are nucleic acids encoding for gNAs (e.g., gRNAs or gDNAs). In some embodiments, by encoding it is meant that a gNA results from the transcription of a nucleic acid encoding for a gNA (e.g., gRNA). In some embodiments, by encoding, it is meant that the nucleic acid is a template for the transcription of a gNA (e.g., gRNA). In some embodiments, by encoding, it is meant that a gNA results from the reverse transcription of a nucleic acid encoding for a gNA. In some embodiments, by encoding, it is meant that the nucleic acid is a template for the reverse transcription of a gNA. In some embodiments, by encoding, it is meant that a gNA results from the amplification of a nucleic acid encoding for a gNA. In some embodiments, by encoding, it is meant that the nucleic acid is a template for the amplification of a gNA.

In some embodiments the nucleic acid encoding for a gNA comprises a first segment comprising a regulatory region; a second segment comprising targeting sequence, wherein the second segment can range from 15 bp-250 bp; and a third segment comprising a nucleic acid encoding a nucleic acid-guided nuclease system (e.g., CRISPR/Cas system) protein-binding sequence.

In some embodiments, the nucleic acids encoding for gNAs comprise DNA. In some embodiments, the first segment is double stranded DNA. In some embodiments, the first segment is single stranded DNA. In some embodiments, the second segment is single stranded DNA. In some embodiments, the third segment is single stranded DNA. In some embodiments, the second segment is double stranded DNA. In some embodiments, the third segment is double stranded DNA.

In some embodiments, the nucleic acids encoding for gNAs comprise RNA.

In some embodiments the nucleic acids encoding for gNAs comprise DNA and RNA.

In some embodiments, the regulatory region is a region capable of binding a transcription factor. In some embodiments, the regulatory region comprises a promoter. In some embodiments, the promoter is selected from the group consisting of T7, SP6, and T3.

Collections of gNAs

Provided herein are collections (interchangeably referred to as libraries) of gNAs.

As used herein, a collection of gNAs denotes a mixture of gNAs containing at least 10² unique gNAs. In some embodiments a collection of gNAs contains at least 10², at least 10³, at least 10⁴, at least 10⁵, at least 10⁶, at least 10⁷, at least 10⁸, at least 10⁹, at least 10¹⁰ unique gNAs. In some embodiments a collection of gNAs contains a total of at least 10², at least 10³, at least 10⁴, at least 10⁵, at least 10⁶, at least 10⁷, at least 10⁸, at least 10⁹, at least 10¹⁰ gNAs.

In some embodiments, a collection of gNAs comprises a first NA segment comprising a targeting sequence; and a second NA segment comprising a nucleic acid-guided nuclease system (e.g., CRISPR/Cas system) protein-binding sequence, wherein at least 10% of the gNAs in the collection vary in size. In some embodiments, the first and second segments are in 5′- to 3′-order′.

In some embodiments, the size of the first segment varies from 15-250 bp, or 30-100 bp, or 22-30 bp, or 15-50 bp, or 15-75 bp, or 15-100 bp, or 15-125 bp, or 15-150 bp, or 15-175 bp, or 15-200 bp, or 15-225 bp, or 15-250 bp, or 22-50 bp, or 22-75 bp, or 22-100 bp, or 22-125 bp, or 22-150 bp, or 22-175 bp, or 22-200 bp, or 22-225 bp, or 22-250 bp across the collection of gNAs.

In some embodiments, at least 10%, or at least 15%, or at last 20%, or at least 25%, or at least 30%, or at least 35%, or at least 40%, or at least 45%, or at least 50%, or at least 55%, or at least 60%, or at least 65%, or at least 70%, or at least 75%, or at least 80%, or at least 85%, or at least 90%, or at least 95%, or 100% of the first segments in the collection are greater than 21 bp.

In some embodiments, at least 10%, or at least 15%, or at last 20%, or at least 25%, or at least 30%, or at least 35%, or at least 40%, or at least 45%, or at least 50%, or at least 55%, or at least 60%, or at least 65%, or at least 70%, or at least 75%, or at least 80%, or at least 85%, or at least 90%, or at least 95%, or 100% of the first segments in the collection are greater than 25 bp.

In some embodiments, at least 10%, or at least 15%, or at last 20%, or at least 25%, or at least 30%, or at least 35%, or at least 40%, or at least 45%, or at least 50%, or at least 55%, or at least 60%, or at least 65%, or at least 70%, or at least 75%, or at least 80%, or at least 85%, or at least 90%, or at least 95%, or 100% of the first segments in the collection are greater than 30 bp.

In some embodiments, at least 10%, or at least 15%, or at last 20%, or at least 25%, or at least 30%, or at least 35%, or at least 40%, or at least 45%, or at least 50%, or at least 55%, or at least 60%, or at least 65%, or at least 70%, or at least 75%, or at least 80%, or at least 85%, or at least 90%, or at least 95%, or 100% of the first segments in the collection are 15-50 bp.

In some embodiments, at least 10%, or at least 15%, or at last 20%, or at least 25%, or at least 30%, or at least 35%, or at least 40%, or at least 45%, or at least 50%, or at least 55%, or at least 60%, or at least 65%, or at least 70%, or at least 75%, or at least 80%, or at least 85%, or at least 90%, or at least 95%, or 100% of the first segments in the collection are 30-100 bp.

In some particular embodiments, the size of the first segment is not 20 bp.

In some particular embodiments, the size of the first segment is not 21 bp.

In some embodiments, the gNAs and/or the targeting sequence of the gNAs in the collection of gRNAs comprise unique 5′ ends. In some embodiments, the collection of gNAs exhibit variability in sequence of the 5′ end of the targeting sequence, across the members of the collection. In some embodiments, the collection of gNAs exhibit variability at least 5%, or at least 10%, or at least 15%, or at last 20%, or at least 25%, or at least 30%, or at least 35%, or at least 40%, or at least 45%, or at least 50%, or at least 55%, or at least 60%, or at least 65%, or at least 70%, or at least 75% variability in the sequence of the 5′ end of the targeting sequence, across the members of the collection.

In some embodiments, the 3′ end of the gNA targeting sequence can be any purine or pyrimidine (and/or modified versions of the same). In some embodiments, the 3′ end of the gNA targeting sequence is an adenine. In some embodiments, the 3′ end of the gNA targeting sequence is a guanine. In some embodiments, the 3′ end of the gNA targeting sequence is a cytosine. In some embodiments, the 3′ end of the gNA targeting sequence is a uracil. In some embodiments, the 3′ end of the gNA targeting sequence is a thymine. In some embodiments, the 3′ end of the gNA targeting sequence is not cytosine.

In some embodiments, the collection of gNAs comprises targeting sequences which can base-pair with the targeted DNA, wherein the target of interest is spaced at least every 1 bp, at least every 2 bp, at least every 3 bp, at least every 4 bp, at least every 5 bp, at least every 6 bp, at least every 7 bp, at least every 8 bp, at least every 9 bp, at least every 10 bp, at least every 11 bp, at least every 12 bp, at least every 13 bp, at least every 14 bp, at least every 15 bp, at least every 16 bp, at least every 17 bp, at least every 18 bp, at least every 19 bp, 20 bp, at least every 25 bp, at least every 30 bp, at least every 40 bp, at least every 50 bp, at least every 100 bp, at least every 200 bp, at least every 300 bp, at least every 400 bp, at least every 500 bp, at least every 600 bp, at least every 700 bp, at least every 800 bp, at least every 900 bp, at least every 1000 bp, at least every 2500 bp, at least every 5000 bp, at least every 10,000 bp, at least every 15,000 bp, at least every 20,000 bp, at least every 25,000 bp, at least every 50,000 bp, at least every 100,000 bp, at least every 250,000 bp, at least every 500,000 bp, at least every 750,000 bp, or even at least every 1,000,000 bp across a genome of interest.

In some embodiments, the collection of gNAs comprises a first NA segment comprising a targeting sequence; and a second NA segment comprising a nucleic acid-guided nuclease system (e.g., CRISPR/Cas system) protein-binding sequence, wherein the gNAs in the collection can have a variety of second NA segments with various specificities for protein members of the nucleic acid-guided nuclease system (e.g., CRISPR/Cas system). For example a collection of gNAs as provided herein, can comprise members whose second segment comprises a nucleic acid-guided nuclease system (e.g., CRISPR/Cas system) protein-binding sequence specific for a first nucleic acid-guided nuclease system (e.g., CRISPR/Cas system) protein; and also comprises members whose second segment comprises a nucleic acid-guided nuclease system (e.g., CRISPR/Cas system) protein-binding sequence specific for a second nucleic acid-guided nuclease system (e.g., CRISPR/Cas system) protein, wherein the first and second nucleic acid-guided nuclease system (e.g., CRISPR/Cas system) proteins are not the same. In some embodiments a collection of gNAs as provided herein comprises members that exhibit specificity to at least 1, at least 2, at least 3, at least 4, at least 5, at least 6, at least 7, at least 8, at least 9, at least 10, at least 11, at least 12, at least 13, at least 14, at least 15, at least 16, at least 17, at least 18, at least 19, or even at least 20 nucleic acid-guided nuclease system (e.g., CRISPR/Cas system) proteins. In one specific embodiment, a collection of gNAs as provided herein comprises members that exhibit specificity for a Cas9 protein and another protein selected from the group consisting of Cpf1, Cas3, Cas8a-c, Cas10, Cse1, Csy1, Csn2, Cas4, Csm2, and Cm5.

In some embodiments, a plurality of the gNA members of the collection are attached to a label, comprise a label or are capable of being labeled. In some embodiments, the gNA comprises is a moiety that is further capable of being attached to a label. A label includes, but is not limited to, enzyme, an enzyme substrate, an antibody, an antigen binding fragment, a peptide, a chromophore, a lumiphore, a fluorophore, a chromogen, a hapten, an antigen, a radioactive isotope, a magnetic particle, a metal nanoparticle, a redox active marker group (capable of undergoing a redox reaction), an aptamer, one member of a binding pair, a member of a FRET pair (either a donor or acceptor fluorophore), and combinations thereof.

In some embodiments, a plurality of the gNA members of the collection are attached to a substrate. The substrate can be made of glass, plastic, silicon, silica-based materials, functionalized polystyrene, functionalized polyethyleneglycol, functionalized organic polymers, nitrocellulose or nylon membranes, paper, cotton, and materials suitable for synthesis. Substrates need not be flat. In some embodiments, the substrate is a 2-dimensional array. In some embodiments, the 2-dimensional array is flat. In some embodiments, the 2-dimensional array is not flat, for example, the array is a wave-like array. Substrates include any type of shape including spherical shapes (e.g., beads). Materials attached to substrates may be attached to any portion of the substrates (e.g., may be attached to an interior portion of a porous substrates material). In some embodiments, the substrate is a 3-dimensional array, for example, a microsphere. In some embodiments, the microsphere is magnetic. In some embodiments, the microsphere is glass. In some embodiments, the microsphere is made of polystyrene. In some embodiments, the microsphere is silica-based. In some embodiments, the substrate is an array with interior surface, for example, is a straw, tube, capillary, cylindrical, or microfluidic chamber array. In some embodiments, the substrate comprises multiple straws, capillaries, tubes, cylinders, or chambers.

Collections of Nucleic Acids Encoding gNAs

Provided herein are collections (interchangeably referred to as libraries) of nucleic acids encoding for gNAs (e.g., gRNAs or gDNAs). In some embodiments, by encoding it is meant that a gNA results from the transcription of a nucleic acid encoding for a gNA. In some embodiments, by encoding, it is meant that the nucleic acid is a template for the transcription of a gNA.

As used herein, a collection of nucleic acids encoding for gNAs denotes a mixture of nucleic acids containing at least 10² unique nucleic acids. In some embodiments a collection of nucleic acids encoding for gNAs contains at least 10², at least 10³, at least 10⁴, at least 10⁵, at least 10⁶, at least 10⁷, at least 10⁸, at least 10⁹, at least 10¹⁰ unique nucleic acids encoding for gNAs. In some embodiments a collection of nucleic acids encoding for gNAs contains a total of at least 10², at least 10³, at least 10⁴, at least 10⁵, at least 10⁶, at least 10⁷, at least 10⁸, at least 10⁹, at least 10¹⁰ nucleic acids encoding for gNAs.

In some embodiments, a collection of nucleic acids encoding for gNAs comprises a first segment comprising a regulatory region; a second segment comprising a targeting sequence; and a third segment comprising a nucleic acid encoding a nucleic acid-guided nuclease system (e.g., CRISPR/Cas system) protein-binding sequence, wherein at least 10% of the nucleic acids in the collection vary in size.

In some embodiments, the first, second, and third segments are in 5′- to 3′-order′.

In some embodiments, the nucleic acids encoding for gNAs comprise DNA. In some embodiments, the first segment is single stranded DNA. In some embodiments, the first segment is double stranded DNA. In some embodiments, the second segment is single stranded DNA. In some embodiments, the third segment is single stranded DNA. In some embodiments, the second segment is double stranded DNA. In some embodiments, the third segment is double stranded DNA.

In some embodiments, the nucleic acids encoding for gNAs comprise RNA.

In some embodiments the nucleic acids encoding for gNAs comprise DNA and RNA.

In some embodiments, the regulatory region is a region capable of binding a transcription factor. In some embodiments, the regulatory region comprises a promoter. In some embodiments, the promoter is selected from the group consisting of T7, SP6, and T3.

In some embodiments, the size of the second segments (targeting sequence) in the collection varies from 15-250 bp, or 30-100 bp, or 22-30 bp, or 15-50 bp, or 15-75 bp, or 15-100 bp, or 15-125 bp, or 15-150 bp, or 15-175 bp, or 15-200 bp, or 15-225 bp, or 15-250 bp, or 22-50 bp, or 22-75 bp, or 22-100 bp, or 22-125 bp, or 22-150 bp, or 22-175 bp, or 22-200 bp, or 22-225 bp, or 22-250 bp across the collection of gNAs.

In some embodiments, at least 10%, or at least 15%, or at last 20%, or at least 25%, or at least 30%, or at least 35%, or at least 40%, or at least 45%, or at least 50%, or at least 55%, or at least 60%, or at least 65%, or at least 70%, or at least 75%, or at least 80%, or at least 85%, or at least 90%, or at least 95%, or 100% of the second segments in the collection are greater than 21 bp.

In some embodiments, at least 10%, or at least 15%, or at last 20%, or at least 25%, or at least 30%, or at least 35%, or at least 40%, or at least 45%, or at least 50%, or at least 55%, or at least 60%, or at least 65%, or at least 70%, or at least 75%, or at least 80%, or at least 85%, or at least 90%, or at least 95%, or 100% of the second segments in the collection are greater than 25 bp.

In some embodiments, at least 10%, or at least 15%, or at last 20%, or at least 25%, or at least 30%, or at least 35%, or at least 40%, or at least 45%, or at least 50%, or at least 55%, or at least 60%, or at least 65%, or at least 70%, or at least 75%, or at least 80%, or at least 85%, or at least 90%, or at least 95%, or 100% of the second segments in the collection are greater than 30 bp.

In some embodiments, at least 10%, or at least 15%, or at last 20%, or at least 25%, or at least 30%, or at least 35%, or at least 40%, or at least 45%, or at least 50%, or at least 55%, or at least 60%, or at least 65%, or at least 70%, or at least 75%, or at least 80%, or at least 85%, or at least 90%, or at least 95%, or 100% of the second segments in the collection are 15-50 bp.

In some embodiments, at least 10%, or at least 15%, or at last 20%, or at least 25%, or at least 30%, or at least 35%, or at least 40%, or at least 45%, or at least 50%, or at least 55%, or at least 60%, or at least 65%, or at least 70%, or at least 75%, or at least 80%, or at least 85%, or at least 90%, or at least 95%, or 100% of the second segments in the collection are 30-100 bp.

In some particular embodiments, the size of the second segment is not 20 bp.

In some particular embodiments, the size of the second segment is not 21 bp.

In some embodiments, the gNAs and/or the targeting sequence of the gNAs in the collection of gNAs comprise unique 5′ ends. In some embodiments, the collection of gNAs exhibit variability in sequence of the 5′ end of the targeting sequence, across the members of the collection. In some embodiments, the collection of gNAs exhibit variability at least 5%, or at least 10%, or at least 15%, or at last 20%, or at least 25%, or at least 30%, or at least 35%, or at least 40%, or at least 45%, or at least 50%, or at least 55%, or at least 60%, or at least 65%, or at least 70%, or at least 75% variability in the sequence of the 5′ end of the targeting sequence, across the members of the collection.

In some embodiments, the collection of nucleic acids comprises targeting sequences, wherein the target of interest is spaced at least every 1 bp, at least every 2 bp, at least every 3 bp, at least every 4 bp, at least every 5 bp, at least every 6 bp, at least every 7 bp, at least every 8 bp, at least every 9 bp, at least every 10 bp, at least every 11 bp, at least every 12 bp, at least every 13 bp, at least every 14 bp, at least every 15 bp, at least every 16 bp, at least every 17 bp, at least every 18 bp, at least every 19 bp, 20 bp, at least every 25 bp, at least every 30 bp, at least every 40 bp, at least every 50 bp, at least every 100 bp, at least every 200 bp, at least every 300 bp, at least every 400 bp, at least every 500 bp, at least every 600 bp, at least every 700 bp, at least every 800 bp, at least every 900 bp, at least every 1000 bp, at least every 2500 bp, at least every 5000 bp, at least every 10,000 bp, at least every 15,000 bp, at least every 20,000 bp, at least every 25,000 bp, at least every 50,000 bp, at least every 100,000 bp, at least every 250,000 bp, at least every 500,000 bp, at least every 750,000 bp, or even at least every 1,000,000 bp across a genome of interest.

In some embodiments, the collection of nucleic acids encoding for gNAs comprise a third segment encoding for a nucleic acid-guided nuclease system (e.g., CRISPR/Cas system) protein-binding sequence, wherein the segments in the collection vary in their specificity for protein members of the nucleic acid-guided nuclease system (e.g., CRISPR/Cas system). For example, a collection of nucleic acids encoding for gNAs as provided herein, can comprise members whose third segment encode for a nucleic acid-guided nuclease system (e.g., CRISPR/Cas system) protein-binding sequence specific for a first nucleic acid-guided nuclease system (e.g., CRISPR/Cas system) protein; and also comprises members whose third segment encodes for a nucleic acid-guided nuclease system (e.g., CRISPR/Cas system) protein-binding sequence specific for a second nucleic acid-guided nuclease system (e.g., CRISPR/Cas system) protein, wherein the first and second nucleic acid-guided nuclease system (e.g., CRISPR/Cas system) proteins are not the same. In some embodiments, a collection of nucleic acids encoding for gNAs as provided herein comprises members that exhibit specificity to at least 1, at least 2, at least 3, at least 4, at least 5, at least 6, at least 7, at least 8, at least 9, at least 10, at least 11, at least 12, at least 13, at least 14, at least 15, at least 16, at least 17, at least 18, at least 19, or even at least 20 nucleic acid-guided nuclease system (e.g., CRISPR/Cas system) proteins. In one specific embodiment, a collection of nucleic acids encoding for gNAs as provided herein comprises members that exhibit specificity for a Cas9 protein and another protein selected from the group consisting of Cpf1, Cas3, Cas8a-c, Cas10, Cse1, Csy1, Csn2, Cas4, Csm2, and Cm5.

Sequences of Interest

Provided herein are gNAs and collections of gNAs, derived from any source DNA (for example from genomic DNA, cDNA, artificial DNA, DNA libraries), that can be used to target sequences of interest in a sample for a variety of applications including, but not limited to, enrichment, depletion, capture, partitioning, labeling, regulation, and editing. The gNAs comprise a targeting sequence, directed at sequences of interest.

In some embodiments, the sequences of interest are genomic sequences (genomic DNA). In some embodiments, the sequences of interest are mammalian genomic sequences. In some embodiments, the sequences of interest are eukaryotic genomic sequences. In some embodiments, the sequences of interest are prokaryotic genomic sequences. In some embodiments, the sequences of interest are viral genomic sequences. In some embodiments, the sequences of interest are bacterial genomic sequences. In some embodiments, the sequences of interest are plant genomic sequences. In some embodiments, the sequences of interest are microbial genomic sequences. In some embodiments, the sequences of interest are genomic sequences from a parasite, for example a eukaryotic parasite. In some embodiments, the sequences of interest are host genomic sequences (e.g., the host organism of a microbiome, a parasite, or a pathogen). In some embodiments, the sequences of interest are abundant genomic sequences, such as sequences from the genome or genomes of the most abundant species in a sample.

In some embodiments, the sequences of interest comprise repetitive DNA. In some embodiments, the sequences of interest comprise abundant DNA. In some embodiments, the sequences of interest comprise mitochondrial DNA. In some embodiments, the sequences of interest comprise ribosomal DNA. In some embodiments, the sequences of interest comprise centromeric DNA. In some embodiments, the sequences of interest comprise DNA comprising Alu elements (Alu DNA). In some embodiments, the sequences of interest comprise long interspersed nuclear elements (LINE DNA). In some embodiments, the sequences of interest comprise short interspersed nuclear elements (SINE DNA). In some embodiments, the abundant DNA comprises ribosomal DNA.

In some embodiments, the sequences of interest comprise single nucleotide polymorphisms (SNPs), short tandem repeats (STRs), cancer genes, inserts, deletions, structural variations, exons, genetic mutations, or regulatory regions.

In some embodiments, the sequences of interest can be a genomic fragment, comprising a region of the genome, or the whole genome itself. In one embodiment, the genome is a DNA genome. In another embodiment, the genome is a RNA genome.

In some embodiments, the sequences of interest are from a eukaryotic or prokaryotic organism; from a mammalian organism or a non-mammalian organism; from an animal or a plant; from a bacteria or virus; from an animal parasite; from a pathogen.

In some embodiments, the sequences of interest are from any mammalian organism. In one embodiment the mammal is a human. In another embodiment the mammal is a livestock animal, for example a horse, a sheep, a cow, a pig, or a donkey. In another embodiment, a mammalian organism is a domestic pet, for example a cat, a dog, a gerbil, a mouse, a rat. In another embodiment the mammal is a type of a monkey.

In some embodiments, the sequences of interest are from any bird or avian organism. An avian organism includes but is not limited to chicken, turkey, duck and goose.

In some embodiments, the sequences of interest are from a plant. In one embodiment, the plant is rice, maize, wheat, rose, grape, coffee, fruit, tomato, potato, or cotton.

In some embodiments, the sequences of interest are from a species of bacteria. In one embodiment, the bacteria are tuberculosis-causing bacteria.

In some embodiments, the sequences of interest are from a virus.

In some embodiments, the sequences of interest are from a species of fungi.

In some embodiments, the sequences of interest are from a species of algae.

In some embodiments, the sequences of interest are from any mammalian parasite.

In some embodiments, the sequences of interest are obtained from any mammalian parasite. In one embodiment, the parasite is a worm. In another embodiment, the parasite is a malaria-causing parasite. In another embodiment, the parasite is a Leishmaniasis-causing parasite. In another embodiment, the parasite is an amoeba.

In some embodiments, the sequences of interest are from a pathogen.

Targeting Sequences

As used herein, a targeting sequence is one that directs the gNA to the sequences of interest in a sample. For example, a targeting sequence targets a particular sequence of interest, for example the targeting sequence targets a genomic sequence of interest.

Provided herein are gNAs and collections of gNAs that comprise a segment that comprises a targeting sequence. Also provided herein, are nucleic acids encoding for gNAs, and collections of nucleic acids encoding for gNAs that comprise a segment encoding for a targeting sequence.

In some embodiments, the targeting sequence comprises DNA.

In some embodiments, the targeting sequence comprises RNA.

In some embodiments, the targeting sequence comprises RNA, and shares at least 70% sequence identity, at least 75% sequence identity, at least 80% sequence identity, at least 85% sequence identity, at least 90% sequence identity, at least 95% sequence identity, or shares 100% sequence identity to a sequence 5′ to a PAM sequence on a sequence of interest, except that the RNA comprises uracils instead of thymines. In some embodiments, the PAM sequence is AGG, CGG, or TGG.

In some embodiments, the targeting sequence comprises DNA, and shares at least 70% sequence identity, at least 75% sequence identity, at least 80% sequence identity, at least 85% sequence identity, at least 90% sequence identity, at least 95% sequence identity, or shares 100% sequence identity to a sequence 5′ to a PAM sequence on a sequence of interest.

In some embodiments, the targeting sequence comprises RNA and is complementary to the strand opposite to a sequence of nucleotides 5′ to a PAM sequence. In some embodiments, the targeting sequence is at least 70% complementary, at least 75% complementary, at least 80% complementary, at least 85% complementary, at least 90% complementary, at least 95% complementary, or is 100% complementary to the strand opposite to a sequence of nucleotides 5′ to a PAM sequence. In some embodiments, the PAM sequence is AGG, CGG, or TGG.

In some embodiments, the targeting sequence comprises DNA and is complementary to the strand opposite to a sequence of nucleotides 5′ to a PAM sequence. In some embodiments, the targeting sequence is at least 70% complementary, at least 75% complementary, at least 80% complementary, at least 85% complementary, at least 90% complementary, at least 95% complementary, or is 100% complementary to the strand opposite to a sequence of nucleotides 5′ to a PAM sequence. In some embodiments, the PAM sequence is AGG, CGG, or TGG.

In some embodiments, a DNA encoding for a targeting sequence of a gRNA shares at least 70% sequence identity, at least 75% sequence identity, at least 80% sequence identity, at least 85% sequence identity, at least 90% sequence identity, at least 95% sequence identity, or shares 100% sequence identity to the strand opposite to a sequence of nucleotides 5′ to a PAM sequence. In some embodiments, the PAM sequence is AGG, CGG, or TGG.

In some embodiments, a DNA encoding for a targeting sequence of a gRNA is complementary to the strand opposite to a sequence of nucleotides 5′ to a PAM sequence and is at least 70% complementary, at least 75% complementary, at least 80% complementary, at least 85% complementary, at least 90% complementary, at least 95% complementary, or is 100% complementary to a sequence 5′ to a PAM sequence on a sequence of interest. In some embodiments, the PAM sequence is AGG, CGG, or TGG.

Nucleic Acid-Guided Nuclease System Proteins

Provided herein are gNAs and collections of gNAs comprising a segment that comprises a nucleic acid-guided nuclease system (e.g., CRISPR/Cas system) protein-binding sequence. Also provided herein, are nucleic acids encoding for gNAs, and collections of nucleic acids encoding for gNAs that comprise a segment encoding a nucleic acid-guided nuclease system (e.g., CRISPR/Cas system) protein-binding sequence. A nucleic acid-guided nuclease system can be an RNA-guided nuclease system. A nucleic acid-guided nuclease system can be a DNA-guided nuclease system.

Methods of the present disclosure can utilize nucleic acid-guided nucleases. As used herein, a “nucleic acid-guided nuclease” is any nuclease that cleaves DNA, RNA or DNA/RNA hybrids, and which uses one or more nucleic acid guide nucleic acids (gNAs) to confer specificity. Nucleic acid-guided nucleases include CRISPR/Cas system proteins as well as non-CRISPR/Cas system proteins.

The nucleic acid-guided nucleases provided herein can be DNA guided DNA nucleases; DNA guided RNA nucleases; RNA guided DNA nucleases; or RNA guided RNA nucleases. The nucleases can be endonucleases. The nucleases can be exonucleases. In one embodiment, the nucleic acid-guided nuclease is a nucleic acid-guided-DNA endonuclease. In one embodiment, the nucleic acid-guided nuclease is a nucleic acid-guided-RNA endonuclease.

A nucleic acid-guided nuclease system protein-binding sequence is a nucleic acid sequence that binds any protein member of a nucleic acid-guided nuclease system. For example, a CRISPR/Cas system protein-binding sequence is a nucleic acid sequence that binds any protein member of a CRISPR/Cas system.

In some embodiments, the nucleic acid-guided nuclease is selected from the group consisting of CAS Class I Type I, CAS Class I Type III, CAS Class I Type IV, CAS Class II Type II, and CAS Class II Type V. In some embodiments, CRISPR/Cas system proteins include proteins from CRISPR Type I systems, CRISPR Type II systems, and CRISPR Type III systems. In some embodiments, the nucleic acid-guided nuclease is selected from the group consisting of Cas9, Cpf1, Cas3, Cas8a-c, Cas10, Cse1, Csy1, Csn2, Cas4, Csm2, Cm5, Csf1, C2c2, and NgAgo.

In some embodiments, nucleic acid-guided nuclease system proteins (e.g., CRISPR/Cas system proteins) can be from any bacterial or archaeal species.

In some embodiments, the nucleic acid-guided nuclease system proteins (e.g., CRISPR/Cas system proteins) are from, or are derived from nucleic acid-guided nuclease system proteins (e.g., CRISPR/Cas system proteins) from Streptococcus pyogenes, Staphylococcus aureus, Neisseria meningitidis, Streptococcus thermophiles, Treponema denticola, Francisella tularensis, Pasteurella multocida, Campylobacter jejuni, Campylobacter lari, Mycoplasma gallisepticum, Nitratifractor salsuginis, Parvibaculum lavamentivorans, Roseburia intestinalis, Neisseria cinerea, Gluconacetobacter diazotrophicus, Azospirillum, Sphaerochaeta globus, Flavobacterium columnare, Fluviicola taffensis, Bacteroides coprophilus, Mycoplasma mobile, Lactobacillus farciminis, Streptococcus pasteurianus, Lactobacillus johnsonii, Staphylococcus pseudintermedius, Filifactor alocis, Legionella pneumophila, Suterella wadsworthensis, or Corynebacter diphtheria.

In some embodiments, examples of nucleic acid-guided nuclease system (e.g., CRISPR/Cas system) proteins can be naturally occurring or engineered versions.

In some embodiments, naturally occurring nucleic acid-guided nuclease system (e.g., CRISPR/Cas system) proteins include Cas9, Cpf1, Cas3, Cas8a-c, Cas10, Cse1, Csy1, Csn2, Cas4, Csm2, and Cm5. Engineered versions of such proteins can also be employed.

In some embodiments, engineered examples of nucleic acid-guided nuclease system (e.g., CRISPR/Cas system) proteins include catalytically dead nucleic acid-guided nuclease system proteins. The term “catalytically dead” generally refers to a nucleic acid-guided nuclease system protein that has inactivated nucleases (e.g., HNH and RuvC nucleases). Such a protein can bind to a target site in any nucleic acid (where the target site is determined by the guide NA), but the protein is unable to cleave or nick the target nucleic acid (e.g., double-stranded DNA). In some embodiments, the nucleic acid-guided nuclease system catalytically dead protein is a catalytically dead CRISPR/Cas system protein, such as catalytically dead Cas9 (dCas9). Accordingly, the dCas9 allows separation of the mixture into unbound nucleic acids and dCas9-bound fragments. In one embodiment, a dCas9/gRNA complex binds to targets determined by the gRNA sequence. The dCas9 bound can prevent cutting by Cas9 while other manipulations proceed. In another embodiment, the dCas9 can be fused to another enzyme, such as a transposase, to target that enzyme's activity to a specific site. Naturally occurring catalytically dead nucleic acid-guided nuclease system proteins can also be employed.

In some embodiments, engineered examples of nucleic acid-guided nuclease (e.g., CRISPR/Cas) system proteins also include nucleic acid-guided nickases (e.g., Cas nickases). A nucleic acid-guided nickase refers to a modified version of a nucleic acid-guided nuclease system protein, containing a single inactive catalytic domain. In one embodiment, the nucleic acid-guided nickase is a Cas nickase, such as Cas9 nickase. A Cas9 nickase may contain a single inactive catalytic domain, for example, either the RuvC- or the HNH-domain. With only one active nuclease domain, the Cas9 nickase cuts only one strand of the target DNA, creating a single-strand break or “nick”. Depending on which mutant is used, the guide NA-hybridized strand or the non-hybridized strand may be cleaved. Nucleic acid-guided nickases bound to 2 gNAs that target opposite strands will create a double-strand break in a target double-stranded DNA. This “dual nickase” strategy can increase the specificity of cutting because it requires that both nucleic acid-guided nuclease/gNA (e.g., Cas9/gRNA) complexes be specifically bound at a site before a double-strand break is formed. Naturally occurring nickase nucleic acid-guided nuclease system proteins can also be employed.

In some embodiments, engineered examples of nucleic acid-guided nuclease system proteins also include nucleic acid-guided nuclease system fusion proteins. For example, a nucleic acid-guided nuclease (e.g., CRISPR/Cas) system protein may be fused to another protein, for example an activator, a repressor, a nuclease, a fluorescent molecule, a radioactive tag, or a transposase.

In some embodiments, the nucleic acid-guided nuclease system protein-binding sequence comprises a gNA (e.g., gRNA) stem-loop sequence.

In some embodiments, a double-stranded DNA sequence encoding the gNA (e.g., gRNA) stem-loop sequence comprises the following DNA sequence on one strand (5′>3′, GTTTTAGAGCTAGAAATAGCAAGTTAAAATAAGGCTAGTCCGTTATCAACTTGAAAAAGTGGCACCG AGTCGGTGCTTTTTTT) (SEQ ID NO: 3), and its reverse-complementary DNA on the other strand (5′>3′, AAAAAAAGCACCGACTCGGTGCCACTTTTTCAAGTTGATAACGGACTAGCCTTATTTTAACTTGCTAT TTCTAGCTCTAAAAC) (SEQ ID NO: 4).

In some embodiments, a single-stranded DNA sequence encoding the gNA (e.g., gRNA) stem-loop sequence comprises the following DNA sequence: (5′>3′, AAAAAAAGCACCGACTCGGTGCCACTTTTTCAAGTTGATAACGGACTAGCCTTATTTTAACTTGCTAT TTCTAGCTCTAAAAC) (SEQ ID NO: 4), wherein the single-stranded DNA serves as a transcription template.

In some embodiments, the gNA (e.g., gRNA) stem-loop sequence comprises the following RNA sequence: (5′>3′, GUUUUAGAGCUAGAAAUAGCAAGUUAAAAUAAGGCUAGUCCGUUAUCAACUUGAAAAAGUGGCA CCGAGUCGGUGCUUUUUUU) (SEQ ID NO: 1)

In some embodiments, a double-stranded DNA sequence encoding the gNA (e.g., gRNA) stem-loop sequence comprises the following DNA sequence on one strand (5′>3′, GTTTTAGAGCTATGCTGGAAACAGCATAGCAAGTTAAAATAAGGCTAGTCCGTTATCAACTTGAAAA AGTGGCACCGAGTCGGTGCTTTTTTTC) (SEQ ID NO: 5), and its reverse-complementary DNA on the other strand (5′>3′, GAAAAAAAGCACCGACTCGGTGCCACTTTTTCAAGTTGATAACGGACTAGCCTTATTTTAACTTGCT ATGCTGTTTCCAGCATAGCTCTAAAAC) (SEQ ID NO: 6).

In some embodiments, a single-stranded DNA sequence encoding the gNA (e.g., gRNA) stem-loop sequence comprises the following DNA sequence: (5′>3′, GAAAAAAAGCACCGACTCGGTGCCACTTTTTCAAGTTGATAACGGACTAGCCTTATTTTAACTTGCT ATGCTGTTTCCAGCATAGCTCTAAAAC) (SEQ ID NO: 6), wherein the single-stranded DNA serves as a transcription template.

In some embodiments, the gNA (e.g., gRNA) stem-loop sequence comprises the following RNA sequence: (5′>3′, GUUUUAGAGCUAUGCUGGAAACAGCAUAGCAAGUUAAAAUAAGGCUAGUCCGUUAUCAACUUGA AAAAGUGGCACCGAGUCGGUGCUUUUUUUC) (SEQ ID NO: 2).

In some embodiments, provided herein is a nucleic acid encoding for a gNA (e.g., gRNA) comprising a first segment comprising a regulatory region; a second segment encoding a targeting sequence; and a third segment comprising a nucleic acid encoding a nucleic acid-guided nuclease (e.g., CRISPR/Cas) system protein-binding sequence. In some embodiments, the third segment comprises a single transcribed component, which upon transcription yields a NA (e.g., RNA) stem-loop sequence. In some embodiments, the third segment comprising a single transcribed component that encodes for the gNA (e.g., gRNA) stem-loop sequence is double-stranded, comprises the following DNA sequence on one strand (5′>3′, GTTTTAGAGCTAGAAATAGCAAGTTAAAATAAGGCTAGTCCGTTATCAACTTGAAAAAGTGGCACCG AGTCGGTGCTTTTTTT) (SEQ ID NO: 3), and its reverse-complementary DNA on the other strand (5′>3′, AAAAAAAGCACCGACTCGGTGCCACTTTTTCAAGTTGATAACGGACTAGCCTTATTTTAACTTGCTAT TTCTAGCTCTAAAAC) (SEQ ID NO: 4). In some embodiments, the third segment comprising a single transcribed component that encodes for the gNA (e.g., gRNA) stem-loop sequence is single-stranded, and comprises the following DNA sequence: (5′>3′, AAAAAAAGCACCGACTCGGTGCCACTTTTTCAAGTTGATAACGGACTAGCCTTATTTTAACTTGCTAT TTCTAGCTCTAAAAC) (SEQ ID NO: 4), wherein the single-stranded DNA serves as a transcription template. In some embodiments, upon transcription from the single transcribed component, the resulting gNA (e.g., gRNA) stem-loop sequence comprises the following RNA sequence: (5′>3′, GUUUUAGAGCUAGAAAUAGCAAGUUAAAAUAAGGCUAGUCCGUUAUCAACUUGAAAAAGUGGCA CCGAGUCGGUGCUUUUUUU) (SEQ ID NO: 1). In some embodiments, the third segment comprising a single transcribed component that encodes for the gNA (e.g., gRNA) stem-loop sequence is double-stranded, comprises the following DNA sequence on one strand (5′>3′, GTTTTAGAGCTATGCTGGAAACAGCATAGCAAGTTAAAATAAGGCTAGTCCGTTATCAACTTGAAAA AGTGGCACCGAGTCGGTGCTTTTTTTC) (SEQ ID NO: 5), and its reverse-complementary DNA on the other strand (5′>3′, GAAAAAAAGCACCGACTCGGTGCCACTTTTTCAAGTTGATAACGGACTAGCCTTATTTTAACTTGCT ATGCTGTTTCCAGCATAGCTCTAAAAC) (SEQ ID NO: 6). In some embodiments, the third segment comprising a single transcribed component that encodes for the gNA (e.g., gRNA) stem-loop sequence is single-stranded, and comprises the following DNA sequence: (5′>3′, GAAAAAAAGCACCGACTCGGTGCCACTTTTTCAAGTTGATAACGGACTAGCCTTATTTTAACTTGCT ATGCTGTTTCCAGCATAGCTCTAAAAC) (SEQ ID NO: 6), wherein the single-stranded DNA serves as a transcription template. In some embodiments, upon transcription from the single transcribed component, the yielded gRNA stem-loop sequence comprises the following RNA sequence: (5′>3′, GUUUUAGAGCUAUGCUGGAAACAGCAUAGCAAGUUAAAAUAAGGCUAGUCCGUUAUCAACUUGA AAAAGUGGCACCGAGUCGGUGCUUUUUUUC) (SEQ ID NO: 2). In some embodiments, the third segment comprises two sub-segments, which encode for a crRNA and a tracrRNA upon transcription. In some embodiment, the crRNA does not comprise the N20 plus the extra sequence which can hybridize with tracrRNA. In some embodiments, the crRNA comprises the extra sequence which can hybridize with tracrRNA. In some embodiments, the two sub-segments are independently transcribed. In some embodiments, the two sub-segments are transcribed as a single unit. In some embodiments, the DNA encoding the crRNA comprises N_(target)GTTTTAGAGCTATGCTGTTTTG (SEQ ID NO: 7), where N_(target) represents the targeting sequence. In some embodiments, the DNA encoding the tracrRNA comprises the sequence GGAACCATTCAAAACAGCATAGCAAGTTAAAATAAGGCTAGTCCGTTATCAACTTGAAAAAGTGGC ACCGAGTCGGTGCTTTTTTT (SEQ ID NO: 8).

In some embodiments, provided herein is a nucleic acid encoding for a gNA (e.g., gRNA) comprising a first segment comprising a regulatory region; a second segment encoding a targeting sequence; and a third segment comprising a nucleic acid encoding a nucleic acid-guided nuclease (e.g., CRISPR/Cas) system protein-binding sequence. In some embodiments, the third segment comprises a DNA sequence, which upon transcription yields a gRNA stem-loop sequence capable of binding a nucleic acid-guided nuclease (e.g., CRISPR/Cas) system protein. In one embodiment, the DNA sequence can be double-stranded. In some embodiments, the third segment double stranded DNA comprises the following DNA sequence on one strand (5′>3′, GTTTTAGAGCTAGAAATAGCAAGTTAAAATAAGGCTAGTCCGTTATCAACTTGAAAAAGTGGCACCG AGTCGGTGCTTTTTTT) (SEQ ID NO: 3), and its reverse-complementary DNA on the other strand (5′>3′, AAAAAAAGCACCGACTCGGTGCCACTTTTTCAAGTTGATAACGGACTAGCCTTATTTTAACTTGCTAT TTCTAGCTCTAAAAC) (SEQ ID NO: 4). In some embodiments, the third segment double stranded DNA comprises the following DNA sequence on one strand (5′>3′, GTTTTAGAGCTATGCTGGAAACAGCATAGCAAGTTAAAATAAGGCTAGTCCGTTATCAACTTGAAAA AGTGGCACCGAGTCGGTGCTTTTTTTC) (SEQ ID NO: 5), and its reverse-complementary DNA on the other strand (5′>3′, GAAAAAAAGCACCGACTCGGTGCCACTTTTTCAAGTTGATAACGGACTAGCCTTATTTTAACTTGCT ATGCTGTTTCCAGCATAGCTCTAAAAC) (SEQ ID NO: 6). In one embodiment, the DNA sequence can be single-stranded. In some embodiments, the third segment single stranded DNA comprises the following DNA sequence (5′>3′, AAAAAAAGCACCGACTCGGTGCCACTTTTTCAAGTTGATAACGGACTAGCCTTATTTTAACTTGCTAT TTCTAGCTCTAAAAC) (SEQ ID NO: 4), wherein the single-stranded DNA serves as a transcription template. In some embodiments, the third segment single stranded DNA comprises the following DNA sequence (5′>3′, GAAAAAAAGCACCGACTCGGTGCCACTTTTTCAAGTTGATAACGGACTAGCCTTATTTTAACTTGCT ATGCTGTTTCCAGCATAGCTCTAAAAC) (SEQ ID NO: 6), wherein the single-stranded DNA serves as a transcription template. In some embodiments, the third segment comprises a DNA sequence which, upon transcription, yields a first RNA sequence that is capable of forming a hybrid with a second RNA sequence, and which hybrid is capable of CRISPR/Cas system protein binding. In some embodiments, the third segment is double-stranded DNA comprising the DNA sequence on one strand: (5′>3′, GTTTTAGAGCTATGCTGTTTTG) (SEQ ID NO: 9) and its reverse complementary DNA sequence on the other strand: (5′>3′, CAAAACAGCATAGCTCTAAAAC) (SEQ ID NO: 10). In some embodiments, the third segment is single-stranded DNA comprising the DNA sequence of (5′>3′, CAAAACAGCATAGCTCTAAAAC) (SEQ ID NO: 10). In some embodiments, the second segment and the third segment together encode for a crRNA sequence. In some embodiments, the second RNA sequence that is capable of forming a hybrid with the first RNA sequence encoded by the third segment of the nucleic acid encoding a gRNA is a tracrRNA. In some embodiments, the tracrRNA comprises the sequence (5′>3′, GGAACCAUUCAAAACAGCAUAGCAAGUUAAAAUAAGGCUAGUCCGUUAUCAACUUGAAAAAGUG GCACCGAGUCGGUGCUUUUUUU) (SEQ ID NO: 11). In some embodiments, the tracrRNA is encoded by a double-stranded DNA comprising sequence of (5′>3′, GGAACCATTCAAAACAGCATAGCAAGTTAAAATAAGGCTAGTCCGTTATCAACTTGAAAAAGTGGC ACCGAGTCGGTGCTTTTTTT) (SEQ ID NO: 8), and optionally fused with a regulatory sequence at its 5′ end. In some embodiments, the regulatory sequence can be bound by a transcription factor. In some embodiments, the regulatory sequence is a promoter. In some embodiments, the regulatory sequence is a T7 promoter, comprising the sequence of (5′>3′, GCCTCGAGCTAATACGACTCACTATAGAG) (SEQ ID NO: 12).

In some embodiments, provided herein is a nucleic acid encoding for a gNA comprising a first segment comprising a regulatory region; a second segment encoding a targeting sequence; and a third segment comprising a nucleic acid encoding a nucleic acid-guided nuclease (e.g., CRISPR/Cas) system protein-binding sequence. In some embodiments, the third segment encodes for a RNA sequence that, upon post-transcriptional cleavage, yields a first RNA segment and a second RNA segment. In some embodiments, the first RNA segment comprises a crRNA and the second RNA segment comprises a tracrRNA, which can form a hybrid and together, provide for nucleic acid-guided nuclease (e.g., CRISPR/Cas) system protein binding. In some embodiments, the third segment further comprises a spacer in between the transcriptional unit for the first RNA segment and the second RNA segment, which spacer comprises an enzyme cleavage site.

In some embodiments, provided herein is a gNA (e.g., gRNA) comprising a first NA segment comprising a targeting sequence and a second NA segment comprising a nucleic acid-guided nuclease (e.g., CRISPR/Cas) system protein-binding sequence. In some embodiments, the size of the first segment is greater than 30 bp. In some embodiments, the second segment comprises a single segment, which comprises the gRNA stem-loop sequence. In some embodiments, the gRNA stem-loop sequence comprises the following RNA sequence: (5′>3′, GUUUUAGAGCUAGAAAUAGCAAGUUAAAAUAAGGCUAGUCCGUUAUCAACUUGAAAAAGUGGCA CCGAGUCGGUGCUUUUUUU) (SEQ ID NO: 1). In some embodiments, the gRNA stem-loop sequence comprises the following RNA sequence: (5′>3′, GUUUUAGAGCUAUGCUGGAAACAGCAUAGCAAGUUAAAAUAAGGCUAGUCCGUUAUCAACUUGA AAAAGUGGCACCGAGUCGGUGCUUUUUUUC) (SEQ ID NO: 2). In some embodiments, the second segment comprises two sub-segments: a first RNA sub-segment (crRNA) that forms a hybrid with a second RNA sub-segment (tracrRNA), which together act to direct nucleic acid-guided nuclease (e.g., CRISPR/Cas) system protein binding. In some embodiments, the sequence of the second sub-segment comprises GUUUUAGAGCUAUGCUGUUUUG. In some embodiments, the first RNA segment and the second RNA segment together forms a crRNA sequence. In some embodiments, the other RNA that will form a hybrid with the second RNA segment is a tracrRNA. In some embodiments the tracrRNA comprises the sequence of 5′>3′, GGAACCAUUCAAAACAGCAUAGCAAGUUAAAAUAAGGCUAGUCCGUUAUCAACUUGAAAAAGUG GCACCGAGUCGGUGCUUUUUUU (SEQ ID NO: 11).

CRISPR/Cas System Nucleic Acid-Guided Nucleases

In some embodiments, CRISPR/Cas system proteins are used in the embodiments provided herein. In some embodiments, CRISPR/Cas system proteins include proteins from CRISPR Type I systems, CRISPR Type II systems, and CRISPR Type III systems.

In some embodiments, CRISPR/Cas system proteins can be from any bacterial or archaeal species.

In some embodiments, the CRISPR/Cas system protein is isolated, recombinantly produced, or synthetic.

In some embodiments, the CRISPR/Cas system proteins are from, or are derived from CRISPR/Cas system proteins from Streptococcus pyogenes, Staphylococcus aureus, Neisseria meningitidis, Streptococcus thermophiles, Treponema denticola, Francisella tularensis, Pasteurella multocida, Campylobacter jejuni, Campylobacter lari, Mycoplasma gallisepticum, Nitratifractor salsuginis, Parvibaculum lavamentivorans, Roseburia intestinalis, Neisseria cinerea, Gluconacetobacter diazotrophicus, Azospirillum, Sphaerochaeta globus, Flavobacterium columnare, Fluviicola taffensis, Bacteroides coprophilus, Mycoplasma mobile, Lactobacillus farciminis, Streptococcus pasteurianus, Lactobacillus johnsonii, Staphylococcus pseudintermedius, Filifactor alocis, Legionella pneumophila, Suterella wadsworthensis, or Corynebacter diphtheria.

In some embodiments, examples of CRISPR/Cas system proteins can be naturally occurring or engineered versions.

In some embodiments, naturally occurring CRISPR/Cas system proteins can belong to CAS Class I Type I, III, or IV, or CAS Class II Type II or V, and can include Cas9, Cas3, Cas8a-c, Cas10, Cse1, Csy1, Csn2, Cas4, Csm2, Cmr5, Csf1, C2c2, and Cpf1.

In an exemplary embodiment, the CRISPR/Cas system protein comprises Cas9.

A “CRISPR/Cas system protein-gNA complex” refers to a complex comprising a CRISPR/Cas system protein and a guide NA (e.g. a gRNA or a gDNA). Where the gNA is a gRNA, the gRNA may be composed of two molecules, i.e., one RNA (“crRNA”) which hybridizes to a target and provides sequence specificity, and one RNA, the “tracrRNA”, which is capable of hybridizing to the crRNA. Alternatively, the guide RNA may be a single molecule (i.e., a gRNA) that contains crRNA and tracrRNA sequences.

A CRISPR/Cas system protein may be at least 60% identical (e.g., at least 70%, at least 80%, or 90% identical, at least 95% identical or at least 98% identical or at least 99% identical) to a wild type CRISPR/Cas system protein. The CRISPR/Cas system protein may have all the functions of a wild type CRISPR/Cas system protein, or only one or some of the functions, including binding activity, nuclease activity, and nuclease activity.

The term “CRISPR/Cas system protein-associated guide NA” refers to a guide NA. The CRISPR/Cas system protein-associated guide NA may exist as isolated NA, or as part of a CRISPR/Cas system protein-gNA complex.

Cas9

In some embodiments, the CRISPR/Cas System protein nucleic acid-guided nuclease is or comprises Cas9. The Cas9 of the present invention can be isolated, recombinantly produced, or synthetic.

Examples of Cas9 proteins that can be used in the embodiments herein can be found in F. A. Ran, L. Cong, W. X. Yan, D. A. Scott, J. S. Gootenberg, A. J. Kriz, B. Zetsche, O. Shalem, X. Wu, K S. Makarova, E. V. Koonin, P. A. Sharp, and F. Zhang; “In vivo genome editing using Staphylococcus aureus Cas9,” Nature 520, 186-191 (9 Apr. 2015) doi:10.1038/nature14299, which is incorporated herein by reference.

In some embodiments, the Cas9 is a Type II CRISPR system derived from Streptococcus pyogenes, Staphylococcus aureus, Neisseria meningitidis, Streptococcus thermophiles, Treponema denticola, Francisella tularensis, Pasteurella multocida, Campylobacter jejuni, Campylobacter lari, Mycoplasma gallisepticum, Nitratifractor salsuginis, Parvibaculum lavamentivorans, Roseburia intestinalis, Neisseria cinerea, Gluconacetobacter diazotrophicus, Azospirillum, Sphaerochaeta globus, Flavobacterium columnare, Fluviicola taffensis, Bacteroides coprophilus, Mycoplasma mobile, Lactobacillus farciminis, Streptococcus pasteurianus, Lactobacillus johnsonii, Staphylococcus pseudintermedius, Filifactor alocis, Legionella pneumophila, Suterella wadsworthensis, or Corynebacter diphtheria.

In some embodiments, the Cas9 is a Type II CRISPR system derived from S. pyogenes and the PAM sequence is NGG located on the immediate 3′ end of the target specific guide sequence. The PAM sequences of Type II CRISPR systems from exemplary bacterial species can also include: Streptococcus pyogenes (NGG), Staph aureus (NNGRRT), Neisseria meningitidis (NNNNGA TT), Streptococcus thermophilus (NNAGAA) and Treponema denticola (NAAAAC) which are all usable without deviating from the present invention.

In one exemplary embodiment, Cas9 sequence can be obtained, for example, from the pX330 plasmid (available from Addgene), re-amplified by PCR then cloned into pET30 (from EMD biosciences) to express in bacteria and purify the recombinant 6His tagged protein.

A “Cas9-gNA complex” refers to a complex comprising a Cas9 protein and a guide NA. A Cas9 protein may be at least 60% identical (e.g., at least 70%, at least 80%, or 90% identical, at least 95% identical or at least 98% identical or at least 99% identical) to a wild type Cas9 protein, e.g., to the Streptococcus pyogenes Cas9 protein. The Cas9 protein may have all the functions of a wild type Cas9 protein, or only one or some of the functions, including binding activity, nuclease activity, and nuclease activity.

The term “Cas9-associated guide NA” refers to a guide NA as described above. The Cas9-associated guide NA may exist isolated, or as part of a Cas9-gNA complex.

Non-CRISPR/Cas System Nucleic Acid-Guided Nucleases

In some embodiments, non-CRISPR/Cas system proteins are used in the embodiments provided herein.

In some embodiments, the non-CRISPR/Cas system proteins can be from any bacterial or archaeal species.

In some embodiments, the non-CRISPR/Cas system protein is isolated, recombinantly produced, or synthetic.

In some embodiments, the non-CRISPR/Cas system proteins are from, or are derived from Aquifex aeolicus, Thermus thermophilus, Streptococcus pyogenes, Staphylococcus aureus, Neisseria meningitidis, Streptococcus thermophiles, Treponema denticola, Francisella tularensis, Pasteurella multocida, Campylobacter jejuni, Campylobacter lari, Mycoplasma gallisepticum, Nitratifractor salsuginis, Parvibaculum lavamentivorans, Roseburia intestinalis, Neisseria cinerea, Gluconacetobacter diazotrophicus, Azospirillum, Sphaerochaeta globus, Flavobacterium columnare, Fluviicola taffensis, Bacteroides coprophilus, Mycoplasma mobile, Lactobacillus farciminis, Streptococcus pasteurianus, Lactobacillus johnsonii, Staphylococcus pseudintermedius, Filifactor alocis, Legionella pneumophila, Suterella wadsworthensis, Natronobacterium gregoryi, or Corynebacter diphtheria.

In some embodiments, the non-CRISPR/Cas system proteins can be naturally occurring or engineered versions.

In some embodiments, a naturally occurring non-CRISPR/Cas system protein is NgAgo (Argonaute from Natronobacterium gregoryi).

A “non-CRISPR/Cas system protein-gNA complex” refers to a complex comprising a non-CRISPR/Cas system protein and a guide NA (e.g. a gRNA or a gDNA). Where the gNA is a gRNA, the gRNA may be composed of two molecules, i.e., one RNA (“crRNA”) which hybridizes to a target and provides sequence specificity, and one RNA, the “tracrRNA”, which is capable of hybridizing to the crRNA. Alternatively, the guide RNA may be a single molecule (i.e., a gRNA) that contains crRNA and tracrRNA sequences.

A non-CRISPR/Cas system protein may be at least 60% identical (e.g., at least 70%, at least 80%, or 90% identical, at least 95% identical or at least 98% identical or at least 99% identical) to a wild type non-CRISPR/Cas system protein. The non-CRISPR/Cas system protein may have all the functions of a wild type non-CRISPR/Cas system protein, or only one or some of the functions, including binding activity, nuclease activity, and nuclease activity.

The term “non-CRISPR/Cas system protein-associated guide NA” refers to a guide NA. The non-CRISPR/Cas system protein-associated guide NA may exist as isolated NA, or as part of a non-CRISPR/Cas system protein-gNA complex.

Catalytically Dead Nucleic Acid-Guided Nucleases

In some embodiments, engineered examples of nucleic acid-guided nucleases include catalytically dead nucleic acid-guided nucleases (CRISPR/Cas system nucleic acid-guided nucleases or non-CRISPR/Cas system nucleic acid-guided nucleases). The term “catalytically dead” generally refers to a nucleic acid-guided nuclease that has inactivated nucleases, for example inactivated HNH and RuvC nucleases. Such a protein can bind to a target site in any nucleic acid (where the target site is determined by the guide NA), but the protein is unable to cleave or nick the nucleic acid.

Accordingly, the catalytically dead nucleic acid-guided nuclease allows separation of the mixture into unbound nucleic acids and catalytically dead nucleic acid-guided nuclease-bound fragments. In one exemplary embodiment, a dCas9/gRNA complex binds to the targets determined by the gRNA sequence. The dCas9 bound can prevent cutting by Cas9 while other manipulations proceed.

In another embodiment, the catalytically dead nucleic acid-guided nuclease can be fused to another enzyme, such as a transposase, to target that enzyme's activity to a specific site.

In some embodiments, the catalytically dead nucleic acid-guided nuclease is dCas9, dCpf1, dCas3, dCas8a-c, dCas10, dCse1, dCsy1, dCsn2, dCas4, dCsm2, dCm5, dCsf1, dC2C2, or dNgAgo.

In one exemplary embodiment the catalytically dead nucleic acid-guided nuclease protein is a dCas9.

Nucleic Acid-Guided Nuclease Nickases

In some embodiments, engineered examples of nucleic acid-guided nucleases include nucleic acid-guided nuclease nickases (referred to interchangeably as nickase nucleic acid-guided nucleases).

In some embodiments, engineered examples of nucleic acid-guided nucleases include CRISPR/Cas system nickases or non-CRISPR/Cas system nickases, containing a single inactive catalytic domain.

In some embodiments, the nucleic acid-guided nuclease nickase is a Cas9 nickase, Cpf1 nickase, Cas3 nickase, Cas8a-c nickase, Cas10 nickase, Cse1 nickase, Csy1 nickase, Csn2 nickase, Cas4 nickase, Csm2 nickase, Cm5 nickase, Csf1 nickase, C2C2 nickase, or a NgAgo nickase.

In one embodiment, the nucleic acid-guided nuclease nickase is a Cas9 nickase.

In some embodiments, a nucleic acid-guided nuclease nickase can be used to bind to target sequence. With only one active nuclease domain, the nucleic acid-guided nuclease nickase cuts only one strand of a target DNA, creating a single-strand break or “nick”. Depending on which mutant is used, the guide NA-hybridized strand or the non-hybridized strand may be cleaved. nucleic acid-guided nuclease nickases bound to 2 gNAs that target opposite strands can create a double-strand break in the nucleic acid. This “dual nickase” strategy increases the specificity of cutting because it requires that both nucleic acid-guided nuclease/gNA complexes be specifically bound at a site before a double-strand break is formed.

In exemplary embodiments, a Cas9 nickase can be used to bind to target sequence. The term “Cas9 nickase” refers to a modified version of the Cas9 protein, containing a single inactive catalytic domain, i.e., either the RuvC- or the HNH-domain. With only one active nuclease domain, the Cas9 nickase cuts only one strand of the target DNA, creating a single-strand break or “nick”. Depending on which mutant is used, the guide RNA-hybridized strand or the non-hybridized strand may be cleaved. Cas9 nickases bound to 2 gRNAs that target opposite strands will create a double-strand break in the DNA. This “dual nickase” strategy can increase the specificity of cutting because it requires that both Cas9/gRNA complexes be specifically bound at a site before a double-strand break is formed.

Capture of DNA can be carried out using a nucleic acid-guided nuclease nickase. In one exemplary embodiment, a nucleic acid-guided nuclease nickase cuts a single strand of double stranded nucleic acid, wherein the double stranded region comprises methylated nucleotides.

Dissociable and Thermostable Nucleic Acid-Guided Nucleases

In some embodiments, thermostable nucleic acid-guided nucleases are used in the methods provided herein (thermostable CRISPR/Cas system nucleic acid-guided nucleases or thermostable non-CRISPR/Cas system nucleic acid-guided nucleases). In such embodiments, the reaction temperature is elevated, inducing dissociation of the protein; the reaction temperature is lowered, allowing for the generation of additional cleaved target sequences. In some embodiments, thermostable nucleic acid-guided nucleases maintain at least 50% activity, at least 55% activity, at least 60% activity, at least 65% activity, at least 70% activity, at least 75% activity, at least 80% activity, at least 85% activity, at least 90% activity, at least 95% activity, at least 96% activity, at least 97% activity, at least 98% activity, at least 99% activity, or 100% activity, when maintained for at least 75° C. for at least 1 minute. In some embodiments, thermostable nucleic acid-guided nucleases maintain at least 50% activity, when maintained for at least 1 minute at least at 75° C., at least at 80° C., at least at 85° C., at least at 90° C., at least at 91° C., at least at 92° C., at least at 93° C., at least at 94° C., at least at 95° C., 96° C., at least at 97° C., at least at 98° C., at least at 99° C., or at least at 100° C. In some embodiments, thermostable nucleic acid-guided nucleases maintain at least 50% activity, when maintained at least at 75° C. for at least 1 minute, 2 minutes, 3 minutes, 4 minutes, or 5 minutes. In some embodiments, a thermostable nucleic acid-guided nuclease maintains at least 50% activity when the temperature is elevated, lowered to 25° C.−50° C. In some embodiments, the temperature is lowered to 25° C., to 30° C., to 35° C., to 40° C., to 45° C., or to 50° C. In one exemplary embodiment, a thermostable enzyme retains at least 90% activity after 1 min at 95° C.

In some embodiments, the thermostable nucleic acid-guided nuclease is thermostable Cas9, thermostable Cpf1, thermostable Cas3, thermostable Cas8a-c, thermostable Cas10, thermostable Cse1, thermostable Csy1, thermostable Csn2, thermostable Cas4, thermostable Csm2, thermostable Cm5, thermostable Csf1, thermostable C2C2, or thermostable NgAgo.

In some embodiments, the thermostable CRISPR/Cas system protein is thermostable Cas9.

Thermostable nucleic acid-guided nucleases can be isolated, for example, identified by sequence homology in the genome of thermophilic bacteria Streptococcus thermophilus and Pyrococcus furiosus. Nucleic acid-guided nuclease genes can then be cloned into an expression vector. In one exemplary embodiment, a thermostable Cas9 protein is isolated.

In another embodiment, a thermostable nucleic acid-guided nuclease can be obtained by in vitro evolution of a non-thermostable nucleic acid-guided nuclease. The sequence of a nucleic acid-guided nuclease can be mutagenized to improve its thermostability.

Methods of Making Collections of gNAs

Provided herein are methods that enable the generation of a large number of diverse gRNAs, collections of gNAs, from any source nucleic acid (e.g., DNA). Methods provided herein can employ enzymatic methods including but not limited to digestion, ligation, extension, overhang filling, transcription, reverse transcription, amplification.

Generally, the method can comprise providing a nucleic acid (e.g., DNA); employing a first enzyme (or combinations of first enzymes) that cuts at a part of the PAM sequence in the nucleic acid, in a way that a residual nucleotide sequence from the PAM sequence is left; ligating an adapter that positions a restriction enzyme typeIIS site (an enzyme that cuts outside yet near its recognition motif) at a distance to eliminate the PAM sequence; employing a second typeIIS enzyme (or combination of second enzymes) to eliminate the PAM sequence together with the adapter; and fusing a sequence that can be recognized by protein members of the nucleic acid-guided nuclease (e.g., CRISPR/Cas) system, for example, a gRNA stem-loop sequence. In some embodiments, the first enzymatic reactions cuts part of the PAM sequence in a way that residual nucleotide sequence from the PAM sequence is left, and that the nucleotide sequence immediately 5′ to the PAM sequence can be any purine or pyrimidine, not just those with a cytosine 5′ to the PAM sequence, for example, not just those that are C/NGG or C/TAG, etc.

Table 1 shows exemplary strategies/protocols to convert any source nucleic acid (e.g., DNA) into a collection of gNAs (e.g., gRNAs) using different restriction enzymes.

TABLE 1 Exemplary strategies for preparing a collection of guide nucleic acids. First 3′ Adapter sequence with CRISPR/Cas Enzyme/ typeIIS enzyme site System PAM Compo- (provided with only one Species Sequence nents Strategy strand sequence 5′ > 3′) Streptococcus NGG CviPII Nicks immediately 5′ of ggGACTCggatccctatagtc pyogenes CCD sequence, nicks the (SEQ ID NO: 4421) (SP); SpCas9 other strand with T7 endonuclease I, blunt with T4 DNA polymerase; ligate to adapter; cut with MlyI to remove PAM and adapter; ligate gRNA stem-loop sequence at 3′ end Staphylococcus NNGRRT AlwI Cut, blunt with T4 DNA ttttagcggccgcctgctgCTCtacaa aureus (SA); or polymerase; ligate to agacgatgacgacaagcgt SaCas9 NNGRR adapter SA; cut with (SEQ ID NO: 4422) (N) EcoP15I to remove PAM and adapter; blunt end; ligate gRNA stem-loop sequence at 3′ end Neisseria NNNNGA TfiI Cut, blunt with T4 DNA TCgcggccgcttttattctgctgCTCt meningitidis TT polymerase; ligate to acaaagacgatgacgacaagcgt (NM) adapter NM; cut with (SEQ ID NO: 4428) EcoRI to eliminate un- wanted DNA and EcoP15I to remove PAM and adapter; blunt end; ligate gRNA stem-loop sequence at 3′ end Streptococcus NNAGAA BsmI Cut, blunt with T4 DNA ttgcggccgcttttattctgctgCTCt thermophilus W polymerase; ligate to acaaagacgatgacgacaagcgt (ST) adapter ST; cut with (SEQ ID NO: 4429) EcoP15I to remove PAM and adapter; blunt end; ligate gRNA stem-loop sequence at 3′ end Treponema NAAAAC Cly7489I Cut, blunt with T4 DNA tttagcggccgcctgctgCTCtacaaa denticola I polymerase; ligate to gacgatgacgacaagcgt (TD) adapter TD; cut with (SEQ ID NO: 4430) EcoP15I to remove PAM and adapter

Table 2 shows additional exemplary strategies/protocols to convert any source nucleic acid (e.g., DNA) into a collection of gNAs (e.g., gRNAs) using different restriction enzymes.

TABLE 2 Additional exemplary strategies for preparing a collection of guide  nucleic acids. First CRISPR/ Enzyme/ Adapter oligo sequence (with Cas System PAM Compo- Exemplary Inosine overhangs, all in Species Sequence nent Strategy 5′ > 3′ direction) Streptococcus NGG CviPII Nicks immediately 5′ of Adapter oligo 1: pyogenes CCD sequence, nicks the ggggGACTCggatccctatagtgatac (SP); SpCas9 other strand with T7 aaagacgatgacgacaagcg endonuclease I; ligate (SEQ ID NO: 4404) to adapter; cut with Adapter oligo 2: MlyI to remove PAM and gcctcgagc*t*a*atacgactcactatag 3′ adapter; ligate ggatccaagtccc gRNA stem-loop sequence (* denotes a phosphorothioate at 3′ end backbone linkage) (SEQ ID NO: 4405) Staphylococcus NNGRRT  AlwI Cut; ligate to adapter Adapter oligo 1: aureus (SA); or SA; cut with EcoP15I IttttagcggccgcctgctgCTCtacaaa SaCas9 NNGRR to remove PAM and 3′ gacgatgacgacaagcgt (N) adapter; blunt end; (SEQ ID NO: 4422) ligate gRNA stem-loop Adapter oligo 2: sequence at 3′ end gagatcagcttctgcattgatgcGAGcag caggcggccgctaaaa (SEQ ID NO: 4423) Neisseria NNNNGATT TfiI Cut; ligate to adapter Adapter oligo 1: meningitidis NM; cut with EcoP15I attTCgcggccgcttttattctgctgCTCt (NM) to remove PAM and 3′ acaaagacgatgacgacaagcgt adapter; blunt end; (SEQ ID NO: 4424) ligate gRNA stem-loop Adapter oligo 2: sequence at 3′ end gagatcagcttctgcattgatgcGAGcag cagaataaaagcggccgcGA (SEQ ID NO: 4425) Streptococcus NNAGAAW BsmI Cut; ligate to adapter Adapter oligo 1: thermophilus ST; cut with EcoP15I gcggccgcttttattctgctgCTCtacaaa (ST) to remove PAM and 3′ gacgatgacgacaagcgt adapter; blunt end; (SEQ ID NO: 4426) ligate gRNA stem-loop Adapter oligo 2: sequence at 3′ end gagatcagcttctgcattgatgcGAGcag cagaataaaagcggccgcIG (SEQ ID NO: 4427)

Exemplary applications of the compositions and methods described herein are provided in FIG. 1, FIG. 2, FIG. 3, FIG. 4, FIG. 5, FIG. 6, and FIG. 7. The figures depict non-limiting exemplary embodiments of the present invention that includes a method of constructing a gNA library (e.g., gRNA library) from input nucleic acids (e.g., DNA), such as genomic DNA (e.g., human genomic DNA).

In FIG. 1, the starting material can be fragmented genomic DNA (e.g., human) or other source DNA. These fragments are blunt-ended before constructing the library 101. T7 promoter adapters are ligated to the blunt-ended DNA fragments 102, which is then PCR amplified. Nt.CviPII is then used to generate a nick on one strand of the PCR product immediately 5′ to the CCD sequence 103. T7 Endonuclease I cleaves on the opposite strand 1, 2, or 3 bp 5′ of the nick 104. The resulting DNA fragments are blunt-ended with T4 DNA Polymerase, leaving HGG sequence at the end of the DNA fragment 105. The resulting DNA is cleaned and recovered on beads. An adapter carrying MlyI recognition site is ligated to the blunt-ended DNA fragment immediately 3′ of HGG sequence 106. MlyI generates a blunt-end cleavage immediately 5′ to the HGG sequence, removing HGG together with the adapter sequence 107. The resulting DNA fragments are cleaned and recovered again on beads. A gRNA stem-loop sequence is then ligated to the blunt-end cleaved by MlyI, forming a gRNA library covering the human genome 108. This library of DNA is then PCR amplified and cleaned on beads, ready for in vitro transcription.

In FIG. 2, the starting material can intact genomic DNA (e.g., human) or other source DNA 201. Nt.CviPII and T7 Endonuclease I are used to generate nicks on each strand of the human genomic DNA, resulting in smaller DNA fragments 202. DNA fragments of 200-600 bp are size selected on beads, then ligated with Y-shaped adapters carrying a GG overhang on the 5′. One strand of the Y-shaped adapter contains a MlyI recognition site, wherein the other strand contains a mutated MlyI site and a T7 promoter sequence 203. Because of these features, after PCR amplification, the T7 promoter sequence is at the distal end of the HGG sequence, and the MlyI sequence is at the rear end of HGG 204. Digestion with MlyI generates a cleavage immediately 5′ of HGG sequence 205. MlyI generates a blunt-end cleavage immediately 5′ to the HGG sequence, removing HGG together with the adapter sequence 206. A gRNA stem-loop sequence is then ligated to the blunt-end cleaved by MlyI, forming a gRNA library covering the human genome. This library of DNA is then PCR amplified and cleaned on beads, ready for in vitro transcription.

In FIG. 3, the source DNA (e.g., genomic DNA) can be nicked 301, for example with a nicking enzyme. In some cases, the nicking enzyme can have a recognition site that is three or fewer bases in length. In some cases, CviPII is used, which can recognize and nick at a sequence of CCD (where D represents a base other than C). Nicks can be proximal, surrounding a region containing the sequence (represented by the thicker line) which will be used to yield the guide RNA N20 sequence. When nicks are proximal, a double stranded break can occur and lead to 5′ or 3′ overhangs 302. These overhangs can be repaired, for example with a polymerase (e.g., T4 polymerase). In some cases, such as with 5′ strands, repair can comprise synthesizing a complementary strand. In some case, such as with 3′ strands, repair can comprise removing overhangs. Repair can result in a blunt end including the N20 guide sequence and a sequence complementary to the nick recognition sequence (e.g., HGG, where H represents a base other than G).

In FIG. 4, continuing for example from the end of FIG. 3, different combinations of adapters can be ligated to the DNA to allow for the desired cleaving. Adapters with a recognition site for a nuclease enzyme that cuts 3 base pairs from the site (e.g., MlyI) can be ligated 401, and digestion at that site can be used to remove a left over sequence, such as an HGG sequence 402. Adapters with a recognition site for a nuclease that cuts 20 base pairs from the site (e.g., MmeI) 403. These adapters can also include a second recognition site for a nuclease that cuts the proper number of nucleotides from the site to later remove the first recognition site (e.g., BsaXI). The first enzyme can be used to cut 20 nucleotides down, thereby keeping the N20 sequence 404. Then, a promoter adapter (e.g., T7) can be ligated next to the N20 sequence 405. Then, the nuclease corresponding to the second recognition site (e.g., BsaXI) can be used to remove the adapter for the site that cuts 20 nucleotides away (e.g., MmeI) 406. Finally, the guide RNA stem-loop sequence adapter can be ligated to the N20 sequence 407 to prepare for guide RNA production.

Alternatively, the protocol shown in FIG. 5 can follow the end of a protocol such as that shown in FIG. 3. Adapters with a recognition site for a nuclease enzyme that cleaves 25 nucleotides from the site (e.g., EcoP15I) can be ligated to the DNA 501. These adapters can also include a second recognition site for a nuclease that cuts the proper number of nucleotides from the site to later remove the first recognition site (e.g., BaeI) and any other left-over sequence, such as HGG. The enzyme corresponding to the first recognition site (e.g., EcoP15I) can then be used to cleave after the N20 sequence 502. Then, a promoter adapter (e.g., T7) can be ligated next to the N20 sequence 503. The enzyme corresponding to the second recognition site (e.g., BaeI) can then be used to remove the recognition sites and any residual sequence (e.g., HGG) 504. Finally, the guide RNA stem-loop sequence adapter can be ligated (e.g., by single strand ligation) to the N20 sequence 505.

As an alternative to protocols such as that shown in FIG. 3, the protocol shown in FIG. 6 can be used in preparation for protocols such as those shown in FIG. 4 or FIG. 5. A nick can be introduced by a nicking enzyme (e.g., CviPII) 601. In some cases, the nick recognition site is three or fewer bases in length. In some cases, CviPII is used, which can recognize and nick at a sequence of CCD. A polymerase (e.g., Bst large fragment DNA polymerase) can then be used to synthesize a new DNA strand starting from the nick while displacing the old strand 602. Because of the DNA synthesis, the nick can be sealed and made available to be nicked again 603. Subsequent cycles of nicking and synthesis can be used to yield large amounts of target sequences 604. These single stranded copies of target sequences can be made double stranded, for example by random priming and extension. These double stranded nucleic acids comprising N20 sequences can then be further processed by methods disclosed herein, such as those shown in FIG. 4 or FIG. 5.

As another alternative to protocols such as that shown in FIG. 3 or FIG. 6, the protocol shown in FIG. 7 can be used in preparation for protocols such as those shown in FIG. 4 or FIG. 5. A nick can be introduced by a nicking enzyme (e.g., CviPII) 701. In some cases, the nicking enzyme recognition site is three or fewer bases in length. In some cases, CviPII is used, which can recognize and nick at a sequence of CCD. A polymerase (e.g., Bst large fragment DNA polymerase) can then be used to synthesize a new DNA strand starting from the nick while displacing the old strand (e.g., nicking endonuclease-mediated strand-displacement DNA amplification (NEMDA)). The reaction parameters can be adjusted to control the size of the single stranded DNA produced. For example, the nickase:polymerase ratio (e.g., CviPII:Bts large fragment polymerase ratio) can be adjusted. Reaction temperature can also be adjusted. Next, an oligonucleotide can be added 704 which has (in the 5′>3′ direction) a promoter (e.g., T7 promoter) 702 followed by a random n-mer (e.g., random 6-mer, random 8-mer) 703. The random n-mer region can bind to a region of the single stranded DNA generated previously. For example, binding can be conducted by denaturing at high temperature followed by rapid cool down, which can allow the random n-mer region to bind to the single stranded DNA generated by NEMDA. In some cases, the DNA is denatured at 98° C. for 7 minutes then cooled down rapidly to 10° C. Extension and/or amplification can be used to produce double-stranded DNA. Blunt ends can be produced, for example enzymatically (e.g., by treatment with DNA polymerase I at 20° C.). This can result in one end ending at the promoter (e.g., T7 promoter) and the other end ending at any nicking enzyme recognition sites (e.g., any CCD sites). These fragments can then be purified, for example by size selection (e.g., by gel purification, capillary electrophoresis, or other fragment separation techniques). In some cases, the target fragments are about 50 base pairs in length (adapter sequence (e.g., T7 adapter)+target N20 sequence+nicking enzyme recognition site or complement (e.g., HGG)). Fragments can then be ligated to an adapter comprising a nuclease recognition site for a nuclease that cuts an appropriate distance away to remove the nicking enzyme recognition site 705. For example, for a three-nucleotide long nicking enzyme recognition site (e.g., CCD for CviPII), BaeI can be used. The appropriate nuclease (e.g., BaeI) can then be used to remove the nuclease recognition site and the nicking enzyme recognition site 706. The remaining nucleic acid sequence (e.g., the N20 site) can then be ligated to the final stem-loop sequence for the guide RNA 707. Amplification (e.g., PCR) can be conducted. Guide RNAs can be produced.

In some embodiments, a collection of gNAs (e.g., gRNAs) targeting human mitochondrial DNA (mtDNA) is created, that can be used for directing nucleic acid-guided nuclease (e.g., Cas9) proteins, comprising the nucleic acid-guided nuclease (e.g., Cas9) target sequence. In some embodiments, the targeting sequence of this collection of gNAs (e.g., gRNAs) are encoded by DNA sequences comprising at least the 20 nt sequence provided in the second column from the right of Table 3 (if the NGG sequence is on positive strand) and Table 4 (if the NGG sequence is on negative strand). In some embodiments, a collection of gRNA nucleic acids, as provided herein, with specificity for human mitochondrial DNA, comprise a plurality of members, wherein the members comprise a plurality of targeting sequences provided in the second column from the right column of Table 3 and/or the second column from the right of Table 4.

TABLE 3 gRNA target sequence for human mtDNA carrying NGG sequence  on the (+) strand. nt sequence on 20 nt gRNA Chr start Chr end the (+) strand target sequence position position containing gRNA SEQ (will encode the SEQ (+ (+ target sequence  ID gRNA targeting ID strand) strand) followed by NGG NO sequence) NO    13    35 ATCACCCTATTAACCAC  13 ATCACCCTATTAACCA 436 TCACGG CTCA    14    36 TCACCCTATTAACCACT  14 TCACCCTATTAACCAC 437 CACGGG TCAC    32    54 ACGGGAGCTCTCCATGC  15 ACGGGAGCTCTCCATG 438 ATTTGG CATT    45    67 ATGCATTTGGTATTTTC  16 ATGCATTTGGTATTTT 439 GTCTGG CGTC    46    68 TGCATTTGGTATTTTCGT  17 TGCATTTGGTATTTTC 440 CTGGG GTCT    47    69 GCATTTGGTATTTTCGT  18 GCATTTGGTATTTTCG 441 CTGGGG TCTG    48    70 CATTTGGTATTTTCGTCT  19 CATTTGGTATTTTCGTC 442 GGGGG TGG    49    71 ATTTGGTATTTTCGTCTG  20 ATTTGGTATTTTCGTCT 443 GGGGG GGG    79   101 GCGATAGCATTGCGAGA  21 GCGATAGCATTGCGAG 444 CGCTGG ACGC    85   107 GCATTGCGAGACGCTGG  22 GCATTGCGAGACGCTG 445 AGCCGG GAGC   163   185 GCACCTACGTTCAATAT  23 GCACCTACGTTCAATA 446 TACAGG TTAC   207   229 GTTAATTAATTAATGCT  24 GTTAATTAATTAATGC 447 TGTAGG TTGT   301   323 AACCCCCCCTCCCCCGC  25 AACCCCCCCTCCCCCG 448 TTCTGG CTTC   388   410 AGATTTCAAATTTTATC  26 AGATTTCAAATTTTAT 449 TTTTGG CTTT   391   413 TTTCAAATTTTATCTTTT  27 TTTCAAATTTTATCTTT 450 GGCGG TGG   604   626 ATACACTGAAAATGTTT  28 ATACACTGAAAATGTT 451 AGACGG TAGA   605   627 TACACTGAAAATGTTTA  29 TACACTGAAAATGTTT 452 GACGGG AGAC   631   653 ACATCACCCCATAAACA  30 ACATCACCCCATAAAC 453 AATAGG AAAT   636   658 ACCCCATAAACAAATAG  31 ACCCCATAAACAAATA 454 GTTTGG GGTT   727   749 TCTAAATCACCACGATC  32 TCTAAATCACCACGAT 455 AAAAGG CAAA   788   810 TTAGCCTAGCCACACCC  33 TTAGCCTAGCCACACC 456 CCACGG CCCA   789   811 TAGCCTAGCCACACCCC  34 TAGCCTAGCCACACCC 457 CACGGG CCAC   851   873 AACTAAGCTATACTAAC  35 AACTAAGCTATACTAA 458 CCCAGG CCCC   852   874 ACTAAGCTATACTAACC  36 ACTAAGCTATACTAAC 459 CCAGGG CCCA   856   878 AGCTATACTAACCCCAG  37 AGCTATACTAACCCCA 460 GGTTGG GGGT   880   902 CAATTTCGTGCCAGCCA  38 CAATTTCGTGCCAGCC 461 CCGCGG ACCG   912   934 TAACCCAAGTCAATAGA  39 TAACCCAAGTCAATAG 462 AGCCGG AAGC  1009  1031 CACAAAATAGACTACG  40 CACAAAATAGACTACG 463 AAAGTGG AAAG  1051  1073 ACAATAGCTAAGACCCA  41 ACAATAGCTAAGACCC 464 AACTGG AAAC  1052  1074 CAATAGCTAAGACCCAA  42 CAATAGCTAAGACCCA 465 ACTGGG AACT  1148  1170 AGCCACAGCTTAAAACT  43 AGCCACAGCTTAAAAC 466 CAAAGG TCAA  1154  1176 AGCTTAAAACTCAAAGG  44 AGCTTAAAACTCAAAG 467 ACCTGG GACC  1157  1179 TTAAAACTCAAAGGACC  45 TTAAAACTCAAAGGAC 468 TGGCGG CTGG  1178  1200 GGTGCTTCATATCCCTC  46 GGTGCTTCATATCCCT 469 TAGAGG CTAG  1267  1289 TCTTCAGCAAACCCTGA  47 TCTTCAGCAAACCCTG 470 TGAAGG ATGA  1306  1328 AGTACCCACGTAAAGAC  48 AGTACCCACGTAAAGA 471 GTTAGG CGTT  1312  1334 CACGTAAAGACGTTAGG  49 CACGTAAAGACGTTAG 472 TCAAGG GTCA  1326  1348 AGGTCAAGGTGTAGCCC  50 AGGTCAAGGTGTAGCC 473 ATGAGG CATG  1329  1351 TCAAGGTGTAGCCCATG  51 TCAAGGTGTAGCCCAT 474 AGGTGG GAGG  1339  1361 GCCCATGAGGTGGCAA  52 GCCCATGAGGTGGCAA 475 GAAATGG GAAA  1340  1362 CCCATGAGGTGGCAAG  53 CCCATGAGGTGGCAAG 476 AAATGGG AAAT  1389  1411 GATAGCCCTTATGAAAC  54 GATAGCCCTTATGAAA 477 TTAAGG CTTA  1390  1412 ATAGCCCTTATGAAACT  55 ATAGCCCTTATGAAAC 478 TAAGGG TTAA  1397  1419 TTATGAAACTTAAGGGT  56 TTATGAAACTTAAGGG 479 CGAAGG TCGA  1400  1422 TGAAACTTAAGGGTCGA  57 TGAAACTTAAGGGTCG 480 AGGTGG AAGG  1441  1463 AGTAGAGTGCTTAGTTG  58 AGTAGAGTGCTTAGTT 481 AACAGG GAAC  1442  1464 GTAGAGTGCTTAGTTGA  59 GTAGAGTGCTTAGTTG 482 ACAGGG AACA  1494  1516 CCTCCTCAAGTATACTT  60 CCTCCTCAAGTATACT 483 CAAAGG TCAA  1530  1552 ACCCCTACGCATTTATA  61 ACCCCTACGCATTTAT 484 TAGAGG ATAG  1548  1570 AGAGGAGACAAGTCGT  62 AGAGGAGACAAGTCG 485 AACATGG TAACA  1560  1582 TCGTAACATGGTAAGTG  63 TCGTAACATGGTAAGT 486 TACTGG GTAC  1573  1595 AGTGTACTGGAAAGTGC  64 AGTGTACTGGAAAGTG 487 ACTTGG CACT  1620  1642 AAAGCACCCAACTTACA  65 AAAGCACCCAACTTAC 488 CTTAGG ACTT  1726  1748 CATTTACCCAAATAAAG  66 CATTTACCCAAATAAA 489 TATAGG GTAT  1746  1768 AGGCGATAGAAATTGA  67 AGGCGATAGAAATTG 490 AACCTGG AAACC  1770  1792 GCAATAGATATAGTACC  68 GCAATAGATATAGTAC 491 GCAAGG CGCA  1771  1793 CAATAGATATAGTACCG  69 CAATAGATATAGTACC 492 CAAGGG GCAA  1809  1831 TAACCAAGCATAATATA  70 TAACCAAGCATAATAT 493 GCAAGG AGCA  1862  1884 TAACTAGAAATAACTTT  71 TAACTAGAAATAACTT 494 GCAAGG TGCA  1947  1969 CCGTCTATGTAGCAAAA  72 CCGTCTATGTAGCAAA 495 TAGTGG ATAG  1948  1970 CGTCTATGTAGCAAAAT  73 CGTCTATGTAGCAAAA 496 AGTGGG TAGT  1960  1982 AAAATAGTGGGAAGAT  74 AAAATAGTGGGAAGA 497 TTATAGG TTTAT  1966  1988 GTGGGAAGATTTATAGG  75 GTGGGAAGATTTATAG 498 TAGAGG GTAG  1987  2009 GGCGACAAACCTACCG  76 GGCGACAAACCTACCG 499 AGCCTGG AGCC  1997  2019 CTACCGAGCCTGGTGAT  77 CTACCGAGCCTGGTGA 500 AGCTGG TAGC  2086  2108 ATTTAACTGTTAGTCCA  78 ATTTAACTGTTAGTCC 501 AAGAGG AAAG  2099  2121 TCCAAAGAGGAACAGC  79 TCCAAAGAGGAACAG 502 TCTTTGG CTCTT  2107  2129 GGAACAGCTCTTTGGAC  80 GGAACAGCTCTTTGGA 503 ACTAGG CACT  2152  2174 AAAAATTTAACACCCAT  81 AAAAATTTAACACCCA 504 AGTAGG TAGT  2247  2269 CTGAACTCCTCACACCC  82 CTGAACTCCTCACACC 505 AATTGG CAAT  2414  2436 CCTCACTGTCAACCCAA  83 CCTCACTGTCAACCCA 506 CACAGG ACAC  2427  2449 CCAACACAGGCATGCTC  84 CCAACACAGGCATGCT 507 ATAAGG CATA  2432  2454 ACAGGCATGCTCATAAG  85 ACAGGCATGCTCATAA 508 GAAAGG GGAA  2449  2471 GAAAGGTTAAAAAAAG  86 GAAAGGTTAAAAAAA 509 TAAAAGG GTAAA  2456  2478 TAAAAAAAGTAAAAGG  87 TAAAAAAAGTAAAAG 510 AACTCGG GAACT  2515  2537 TCTAGCATCACCAGTAT  88 TCTAGCATCACCAGTA 511 TAGAGG TTAG  2546  2568 GCCCAGTGACACATGTT  89 GCCCAGTGACACATGT 512 TAACGG TTAA  2552  2574 TGACACATGTTTAACGG  90 TGACACATGTTTAACG 513 CCGCGG GCCG  2571  2593 GCGGTACCCTAACCGTG  91 GCGGTACCCTAACCGT 514 CAAAGG GCAA  2599  2621 TAATCACTTGTTCCTTA  92 TAATCACTTGTTCCTT 515 AATAGG AAAT  2600  2622 AATCACTTGTTCCTTAA  93 AATCACTTGTTCCTTA 516 ATAGGG AATA  2614  2636 TAAATAGGGACCTGTAT  94 TAAATAGGGACCTGTA 517 GAATGG TGAA  2624  2646 CCTGTATGAATGGCTCC  95 CCTGTATGAATGGCTC 518 ACGAGG CACG  2625  2647 CTGTATGAATGGCTCCA  96 CTGTATGAATGGCTCC 519 CGAGGG ACGA  2676  2698 AAATTGACCTGCCCGTG  97 AAATTGACCTGCCCGT 520 AAGAGG GAAG  2679  2701 TTGACCTGCCCGTGAAG  98 TTGACCTGCCCGTGAA 521 AGGCGG GAGG  2680  2702 TGACCTGCCCGTGAAGA  99 TGACCTGCCCGTGAAG 522 GGCGGG AGGC  2711  2733 AGCAAGACGAGAAGAC 100 AGCAAGACGAGAAGA 523 CCTATGG CCCTA  2755  2777 ACAGTACCTAACAAACC 101 ACAGTACCTAACAAAC 524 CACAGG CCAC  2789  2811 CAAACCTGCATTAAAAA 102 CAAACCTGCATTAAAA 525 TTTCGG ATTT  2793  2815 CCTGCATTAAAAATTTC 103 CCTGCATTAAAAATTT 526 GGTTGG CGGT  2794  2816 CTGCATTAAAAATTTCG 104 CTGCATTAAAAATTTC 527 GTTGGG GGTT  2795  2817 TGCATTAAAAATTTCGG 105 TGCATTAAAAATTTCG 528 TTGGGG GTTG  2804  2826 AATTTCGGTTGGGGCGA 106 AATTTCGGTTGGGGCG 529 CCTCGG ACCT  2895  2917 TGATCCAATAACTTGAC 107 TGATCCAATAACTTGA 530 CAACGG CCAA  2911  2933 CCAACGGAACAAGTTAC 108 CCAACGGAACAAGTTA 531 CCTAGG CCCT  2912  2934 CAACGGAACAAGTTACC 109 CAACGGAACAAGTTAC 532 CTAGGG CCTA  2954  2976 CTAGAGTCCATATCAAC 110 CTAGAGTCCATATCAA 533 AATAGG CAAT  2955  2977 TAGAGTCCATATCAACA 111 TAGAGTCCATATCAAC 534 ATAGGG AATA  2974  2996 AGGGTTTACGACCTCGA 112 AGGGTTTACGACCTCG 535 TGTTGG ATGT  2980  3002 TACGACCTCGATGTTGG 113 TACGACCTCGATGTTG 536 ATCAGG GATC  2992  3014 GTTGGATCAGGACATCC 114 GTTGGATCAGGACATC 537 CGATGG CCGA  3010  3032 GATGGTGCAGCCGCTAT 115 GATGGTGCAGCCGCTA 538 TAAAGG TTAA  3058  3080 TACGTGATCTGAGTTCA 116 TACGTGATCTGAGTTC 539 GACCGG AGAC  3069  3091 AGTTCAGACCGGAGTAA 117 AGTTCAGACCGGAGTA 540 TCCAGG ATCC  3073  3095 CAGACCGGAGTAATCCA 118 CAGACCGGAGTAATCC 541 GGTCGG AGGT  3110  3132 CAAATTCCTCCCTGTAC 119 CAAATTCCTCCCTGTA 542 GAAAGG CGAA  3125  3147 ACGAAAGGACAAGAGA 120 ACGAAAGGACAAGAG 543 AATAAGG AAATA  3203  3225 ACCCACACCCACCCAAG 121 ACCCACACCCACCCAA 544 AACAGG GAAC  3204  3226 CCCACACCCACCCAAGA 122 CCCACACCCACCCAAG 545 ACAGGG AACA  3217  3239 AAGAACAGGGTTTGTTA 123 AAGAACAGGGTTTGTT 546 AGATGG AAGA  3227  3249 TTTGTTAAGATGGCAGA 124 TTTGTTAAGATGGCAG 547 GCCCGG AGCC  3262  3284 ACTTAAAACTTTACAGT 125 ACTTAAAACTTTACAG 548 CAGAGG TCAG  3294  3316 TCTTCTTAACAACATAC 126 TCTTCTTAACAACATA 549 CCATGG CCCA  3336  3358 TGTACCCATTCTAATCG 127 TGTACCCATTCTAATC 550 CAATGG GCAA  3370  3392 CTTACCGAACGAAAAAT 128 CTTACCGAACGAAAAA 551 TCTAGG TTCT  3391  3413 GGCTATATACAACTACG 129 GGCTATATACAACTAC 552 CAAAGG GCAA  3406  3428 CGCAAAGGCCCCAACGT 130 CGCAAAGGCCCCAAC 553 TGTAGG GTTGT  3415  3437 CCCAACGTTGTAGGCCC 131 CCCAACGTTGTAGGCC 554 CTACGG CCTA  3416  3438 CCAACGTTGTAGGCCCC 132 CCAACGTTGTAGGCCC 555 TACGGG CTAC  3570  3592 CCTCCCCATACCCAACC 133 CCTCCCCATACCCAAC 556 CCCTGG CCCC  3586  3608 CCCCTGGTCAACCTCAA 134 CCCCTGGTCAACCTCA 557 CCTAGG ACCT  3643  3665 GTTTACTCAATCCTCTG 135 GTTTACTCAATCCTCT 558 ATCAGG GATC  3644  3666 TTTACTCAATCCTCTGA 136 TTTACTCAATCCTCTG 559 TCAGGG ATCA  3676  3698 AACTCAAACTACGCCCT 137 AACTCAAACTACGCCC 560 GATCGG TGAT  3757  3779 CTATCAACATTACTAAT 138 CTATCAACATTACTAA 561 AAGTGG TAAG  3828  3850 ACTCCTGCCATCATGAC 139 ACTCCTGCCATCATGA 562 CCTTGG CCCT  3892  3914 ACCCCCTTCGACCTTGC 140 ACCCCCTTCGACCTTG 563 CGAAGG CCGA  3893  3915 CCCCCTTCGACCTTGCC 141 CCCCCTTCGACCTTGC 564 GAAGGG CGAA  3894  3916 CCCCTTCGACCTTGCCG 142 CCCCTTCGACCTTGCC 565 AAGGGG GAAG  3913  3935 GGGGAGTCCGAACTAGT 143 GGGGAGTCCGAACTA 566 CTCAGG GTCTC  3937  3959 TTCAACATCGAATACGC 144 TTCAACATCGAATACG 567 CGCAGG CCGC  4015  4037 CTCACCACTACAATCTT 145 CTCACCACTACAATCT 568 CCTAGG TCCT  4287  4309 ACTTTGATAGAGTAAAT 146 ACTTTGATAGAGTAAA 569 AATAGG TAAT  4311  4333 GCTTAAACCCCCTTATT 147 GCTTAAACCCCCTTAT 570 TCTAGG TTCT  4386  4408 TCACACCCCATCCTAAA 148 TCACACCCCATCCTAA 571 GTAAGG AGTA  4406  4428 AGGTCAGCTAAATAAGC 149 AGGTCAGCTAAATAAG 572 TATCGG CTAT  4407  4429 GGTCAGCTAAATAAGCT 150 GGTCAGCTAAATAAGC 573 ATCGGG TATC  4428  4450 GGCCCATACCCCGAAAA 151 GGCCCATACCCCGAAA 574 TGTTGG ATGT  4460  4482 TCCCGTACTAATTAATC 152 TCCCGTACTAATTAAT 575 CCCTGG CCCC  4494  4516 ATCTACTCTACCATCTTT 153 ATCTACTCTACCATCT 576 GCAGG TTGC  4542  4564 CACTGATTTTTTACCTG 154 CACTGATTTTTTACCT 577 AGTAGG GAGT  4692  4714 CTCTTCAACAATATACT 155 CTCTTCAACAATATAC 578 CTCCGG TCTC  4767  4789 ATAGCTATAGCAATAAA 156 ATAGCTATAGCAATAA 579 ACTAGG AACT  4799  4821 CTTTCACTTCTGAGTCC 157 CTTTCACTTCTGAGTC 580 CAGAGG CCAG  4809  4831 TGAGTCCCAGAGGTTAC 158 TGAGTCCCAGAGGTTA 581 CCAAGG CCCA  4827  4849 CAAGGCACCCCTCTGAC 159 CAAGGCACCCCTCTGA 582 ATCCGG CATC  4941  4963 TCAATCTTATCCATCAT 160 TCAATCTTATCCATCA 583 AGCAGG TAGC  4950  4972 TCCATCATAGCAGGCAG 161 TCCATCATAGCAGGCA 584 TTGAGG GTTG  4953  4975 ATCATAGCAGGCAGTTG 162 ATCATAGCAGGCAGTT 585 AGGTGG GAGG  5010  5032 TACTCCTCAATTACCCA 163 TACTCCTCAATTACCC 586 CATAGG ACAT  5202  5224 CCATCCACCCTCCTCTC 164 CCATCCACCCTCCTCT 587 CCTAGG CCCT  5205  5227 TCCACCCTCCTCTCCCT 165 TCCACCCTCCTCTCCCT 588 AGGAGG AGG  5223  5245 GGAGGCCTGCCCCCGCT 166 GGAGGCCTGCCCCCGC 589 AACCGG TAAC  5239  5261 TAACCGGCTTTTTGCCC 167 TAACCGGCTTTTTGCC 590 AAATGG CAAA  5240  5262 AACCGGCTTTTTGCCCA 168 AACCGGCTTTTTGCCC 591 AATGGG AAAT  5500  5522 TAATAATCTTATAGAAA 169 TAATAATCTTATAGAA 592 TTTAGG ATTT  5569  5591 CTTAATTTCTGTAACAG 170 CTTAATTTCTGTAACA 593 CTAAGG GCTA  5646  5668 CTAAGCCCTTACTAGAC 171 CTAAGCCCTTACTAGA 594 CAATGG CCAA  5647  5669 TAAGCCCTTACTAGACC 172 TAAGCCCTTACTAGAC 595 AATGGG CAAT  5697  5719 AGCTAAGCACCCTAATC 173 AGCTAAGCACCCTAAT 596 AACTGG CAAC  5723  5745 CAATCTACTTCTCCCGC 174 CAATCTACTTCTCCCG 597 CGCCGG CCGC  5724  5746 AATCTACTTCTCCCGCC 175 AATCTACTTCTCCCGC 598 GCCGGG CGCC  5732  5754 TCTCCCGCCGCCGGGAA 176 TCTCCCGCCGCCGGGA 599 AAAAGG AAAA  5735  5757 CCCGCCGCCGGGAAAA 177 CCCGCCGCCGGGAAA 600 AAGGCGG AAAGG  5736  5758 CCGCCGCCGGGAAAAA 178 CCGCCGCCGGGAAAA 601 AGGCGGG AAGGC  5747  5769 AAAAAAGGCGGGAGAA 179 AAAAAAGGCGGGAGA 602 GCCCCGG AGCCC  5751  5773 AAGGCGGGAGAAGCCC 180 AAGGCGGGAGAAGCC 603 CGGCAGG CCGGC  5800  5822 ATTCAATATGAAAATCA 181 ATTCAATATGAAAATC 604 CCTCGG ACCT  5806  5828 TATGAAAATCACCTCGG 182 TATGAAAATCACCTCG 605 AGCTGG GAGC  5816  5838 ACCTCGGAGCTGGTAAA 183 ACCTCGGAGCTGGTAA 606 AAGAGG AAAG  5928  5950 TCTACAAACCACAAAGA 184 TCTACAAACCACAAAG 607 CATTGG ACAT  5949  5971 GGAACACTATACCTATT 185 GGAACACTATACCTAT 608 ATTCGG TATT  5961  5983 CTATTATTCGGCGCATG 186 CTATTATTCGGCGCAT 609 AGCTGG GAGC  5970  5992 GGCGCATGAGCTGGAGT 187 GGCGCATGAGCTGGA 610 CCTAGG GTCCT  6005  6027 CCTCCTTATTCGAGCCG 188 CCTCCTTATTCGAGCC 611 AGCTGG GAGC  6006  6028 CTCCTTATTCGAGCCGA 189 CTCCTTATTCGAGCCG 612 GCTGGG AGCT  6027  6049 GGCCAGCCAGGCAACCT 190 GGCCAGCCAGGCAAC 613 TCTAGG CTTCT  6108  6130 ATAGTAATACCCATCAT 191 ATAGTAATACCCATCA 614 AATCGG TAAT  6111  6133 GTAATACCCATCATAAT 192 GTAATACCCATCATAA 615 CGGAGG TCGG  6117  6139 CCCATCATAATCGGAGG 193 CCCATCATAATCGGAG 616 CTTTGG GCTT  6144  6166 TGACTAGTTCCCCTAAT 194 TGACTAGTTCCCCTAA 617 AATCGG TAAT  6158  6180 AATAATCGGTGCCCCCG 195 AATAATCGGTGCCCCC 618 ATATGG GATA  6236  6258 CCTGCTCGCATCTGCTA 196 CCTGCTCGCATCTGCT 619 TAGTGG ATAG  6239  6261 GCTCGCATCTGCTATAG 197 GCTCGCATCTGCTATA 620 TGGAGG GTGG  6243  6265 GCATCTGCTATAGTGGA 198 GCATCTGCTATAGTGG 621 GGCCGG AGGC  6249  6271 GCTATAGTGGAGGCCGG 199 GCTATAGTGGAGGCCG 622 AGCAGG GAGC  6255  6277 GTGGAGGCCGGAGCAG 200 GTGGAGGCCGGAGCA 623 GAACAGG GGAAC  6282  6304 ACAGTCTACCCTCCCTT 201 ACAGTCTACCCTCCCT 624 AGCAGG TAGC  6283  6305 CAGTCTACCCTCCCTTA 202 CAGTCTACCCTCCCTT 625 GCAGGG AGCA  6300  6322 GCAGGGAACTACTCCCA 203 GCAGGGAACTACTCCC 626 CCCTGG ACCC  6342  6364 ATCTTCTCCTTACACCT 204 ATCTTCTCCTTACACCT 627 AGCAGG AGC  6360  6382 GCAGGTGTCTCCTCTAT 205 GCAGGTGTCTCCTCTA 628 CTTAGG TCTT  6361  6383 CAGGTGTCTCCTCTATC 206 CAGGTGTCTCCTCTAT 629 TTAGGG CTTA  6362  6384 AGGTGTCTCCTCTATCT 207 AGGTGTCTCCTCTATC 630 TAGGGG TTAG  6495  6517 TCTCTCCCAGTCCTAGC 208 TCTCTCCCAGTCCTAG 631 TGCTGG CTGC  6552  6574 ACCACCTTCTTCGACCC 209 ACCACCTTCTTCGACC 632 CGCCGG CCGC  6555  6577 ACCTTCTTCGACCCCGC 210 ACCTTCTTCGACCCCG 633 CGGAGG CCGG  6558  6580 TTCTTCGACCCCGCCGG 211 TTCTTCGACCCCGCCG 634 AGGAGG GAGG  6597  6619 CAACACCTATTCTGATT 212 CAACACCTATTCTGAT 635 TTTCGG TTTT  6630  6652 GTTTATATTCTTATCCTA 213 GTTTATATTCTTATCCT 636 CCAGG ACC  6636  6658 ATTCTTATCCTACCAGG 214 ATTCTTATCCTACCAG 637 CTTCGG GCTT  6669  6691 CATATTGTAACTTACTA 215 CATATTGTAACTTACT 638 CTCCGG ACTC  6687  6709 TCCGGAAAAAAAGAAC 216 TCCGGAAAAAAAGAA 639 CATTTGG CCATT  6696  6718 AAAGAACCATTTGGATA 217 AAAGAACCATTTGGAT 640 CATAGG ACAT  6701  6723 ACCATTTGGATACATAG 218 ACCATTTGGATACATA 641 GTATGG GGTA  6723  6745 GTCTGAGCTATGATATC 219 GTCTGAGCTATGATAT 642 AATTGG CAAT  6732  6754 ATGATATCAATTGGCTT 220 ATGATATCAATTGGCT 643 CCTAGG TCCT  6733  6755 TGATATCAATTGGCTTC 221 TGATATCAATTGGCTT 644 CTAGGG CCTA  6768  6790 GCACACCATATATTTAC 222 GCACACCATATATTTA 645 AGTAGG CAGT  6831  6853 ATAATCATCGCTATCCC 223 ATAATCATCGCTATCC 646 CACCGG CCAC  6867  6889 AGCTGACTCGCCACACT 224 AGCTGACTCGCCACAC 647 CCACGG TCCA  6909  6931 GCTGCAGTGCTCTGAGC 225 GCTGCAGTGCTCTGAG 648 CCTAGG CCCT  6933  6955 TTCATCTTTCTTTTCACC 226 TTCATCTTTCTTTTCAC 649 GTAGG CGT  6936  6958 ATCTTTCTTTTCACCGTA 227 ATCTTTCTTTTCACCGT 650 GGTGG AGG  6945  6967 TTCACCGTAGGTGGCCT 228 TTCACCGTAGGTGGCC 651 GACTGG TGAC  7032  7054 TTCCACTATGTCCTATC 229 TTCCACTATGTCCTAT 652 AATAGG CAAT  7053  7075 GGAGCTGTATTTGCCAT 230 GGAGCTGTATTTGCCA 653 CATAGG TCAT  7056  7078 GCTGTATTTGCCATCAT 231 GCTGTATTTGCCATCA 654 AGGAGG TAGG  7086  7108 CACTGATTTCCCCTATT 232 CACTGATTTCCCCTAT 655 CTCAGG TCTC  7140  7162 CATTTCACTATCATATT 233 CATTTCACTATCATAT 656 CATCGG TCAT  7176  7198 TTCTTCCCACAACACTT 234 TTCTTCCCACAACACT 657 TCTCGG TTCT  7185  7207 CAACACTTTCTCGGCCT 235 CAACACTTTCTCGGCC 658 ATCCGG TATC  7205  7227 CGGAATGCCCCGACGTT 236 CGGAATGCCCCGACGT 659 ACTCGG TACT  7251  7273 TGAAACATCCTATCATC 237 TGAAACATCCTATCAT 660 TGTAGG CTGT  7358  7380 AGAAGAACCCTCCATAA 238 AGAAGAACCCTCCATA 661 ACCTGG AACC  7371  7393 ATAAACCTGGAGTGACT 239 ATAAACCTGGAGTGAC 662 ATATGG TATA  7432  7454 ACATAAAATCTAGACAA 240 ACATAAAATCTAGACA 663 AAAAGG AAAA  7436  7458 AAAATCTAGACAAAAA 241 AAAATCTAGACAAAA 664 AGGAAGG AAGGA  7457  7479 GGAATCGAACCCCCCAA 242 GGAATCGAACCCCCCA 665 AGCTGG AAGC  7476  7498 CTGGTTTCAAGCCAACC 243 CTGGTTTCAAGCCAAC 666 CCATGG CCCA  7499  7521 CCTCCATGACTTTTTCA 244 CCTCCATGACTTTTTC 667 AAAAGG AAAA  7544  7566 CTTTGTCAAAGTTAAAT 245 CTTTGTCAAAGTTAAA 668 TATAGG TTAT  7567  7589 CTAAATCCTATATATCT 246 CTAAATCCTATATATC 669 TAATGG TTAA  7586  7608 ATGGCACATGCAGCGCA 247 ATGGCACATGCAGCGC 670 AGTAGG AAGT  7741  7763 TACTAACATCTCAGACG 248 TACTAACATCTCAGAC 671 CTCAGG GCTC  7831  7853 CATCCTTTACATAACAG 249 CATCCTTTACATAACA 672 ACGAGG GACG  7865  7887 TCCCTTACCATCAAATC 250 TCCCTTACCATCAAAT 673 AATTGG CAAT  7875  7897 TCAAATCAATTGGCCAC 251 TCAAATCAATTGGCCA 674 CAATGG CCAA  7904  7926 ACCTACGAGTACACCGA 252 ACCTACGAGTACACCG 675 CTACGG ACTA  7907  7929 TACGAGTACACCGACTA 253 TACGAGTACACCGACT 676 CGGCGG ACGG  7955  7977 CCCCCATTATTCCTAGA 254 CCCCCATTATTCCTAG 677 ACCAGG AACC  8069  8091 TCATGAGCTGTCCCCAC 255 TCATGAGCTGTCCCCA 678 ATTAGG CATT  8093  8115 TTAAAAACAGATGCAAT 256 TTAAAAACAGATGCAA 679 TCCCGG TTCC  8131  8153 CACTTTCACCGCTACAC 257 CACTTTCACCGCTACA 680 GACCGG CGAC  8132  8154 ACTTTCACCGCTACACG 258 ACTTTCACCGCTACAC 681 ACCGGG GACC  8133  8155 CTTTCACCGCTACACGA 259 CTTTCACCGCTACACG 682 CCGGGG ACCG  8134  8156 TTTCACCGCTACACGAC 260 TTTCACCGCTACACGA 683 CGGGGG CCGG  8144  8166 ACACGACCGGGGGTAT 261 ACACGACCGGGGGTAT 684 ACTACGG ACTA  8165  8187 GGTCAATGCTCTGAAAT 262 GGTCAATGCTCTGAAA 685 CTGTGG TCTG  8228  8250 CCCCTAAAAATCTTTGA 263 CCCCTAAAAATCTTTG 686 AATAGG AAAT  8229  8251 CCCTAAAAATCTTTGAA 264 CCCTAAAAATCTTTGA 687 ATAGGG AATA  8370  8392 CCCAACTAAATACTACC 265 CCCAACTAAATACTAC 688 GTATGG CGTA  8551  8573 TTCATTGCCCCCACAAT 266 TTCATTGCCCCCACAA 689 CCTAGG TCCT  8698  8720 ATAACCATACACAACAC 267 ATAACCATACACAACA 690 TAAAGG CTAA  8761  8783 ATTGCCACAACTAACCT 268 ATTGCCACAACTAACC 691 CCTCGG TCCT  8817  8839 ACTATCTATAAACCTAG 269 ACTATCTATAAACCTA 692 CCATGG GCCA  8835  8857 CATGGCCATCCCCTTAT 270 CATGGCCATCCCCTTA 693 GAGCGG TGAG  8836  8858 ATGGCCATCCCCTTATG 271 ATGGCCATCCCCTTAT 694 AGCGGG GAGC  8851  8873 TGAGCGGGCACAGTGAT 272 TGAGCGGGCACAGTG 695 TATAGG ATTAT  8899  8921 CTAGCCCACTTCTTACC 273 CTAGCCCACTTCTTAC 696 ACAAGG CACA  8973  8995 ACTCATTCAACCAATAG 274 ACTCATTCAACCAATA 697 CCCTGG GCCC  9004  9026 CTAACCGCTAACATTAC 275 CTAACCGCTAACATTA 698 TGCAGG CTGC  9028  9050 CACCTACTCATGCACCT 276 CACCTACTCATGCACC 699 AATTGG TAAT  9243  9265 CCCAGCCCATGACCCCT 277 CCCAGCCCATGACCCC 700 AACAGG TAAC  9244  9266 CCAGCCCATGACCCCTA 278 CCAGCCCATGACCCCT 701 ACAGGG AACA  9245  9267 CAGCCCATGACCCCTAA 279 CAGCCCATGACCCCTA 702 CAGGGG ACAG  9273  9295 TCAGCCCTCCTAATGAC 280 TCAGCCCTCCTAATGA 703 CTCCGG CCTC  9321  9343 TCCATAACGCTCCTCAT 281 TCCATAACGCTCCTCA 704 ACTAGG TACT  9358  9380 CACTAACCATATACCAA 282 CACTAACCATATACCA 705 TGATGG ATGA  9390  9412 ACACGAGAAAGCACAT 283 ACACGAGAAAGCACA 706 ACCAAGG TACCA  9417  9439 CACACACCACCTGTCCA 284 CACACACCACCTGTCC 707 AAAAGG AAAA  9429  9451 GTCCAAAAAGGCCTTCG 285 GTCCAAAAAGGCCTTC 708 ATACGG GATA  9430  9452 TCCAAAAAGGCCTTCGA 286 TCCAAAAAGGCCTTCG 709 TACGGG ATAC  9471  9493 TCAGAAGTTTTTTTCTTC 287 TCAGAAGTTTTTTTCTT 710 GCAGG CGC  9522  9544 CTAGCCCCTACCCCCCA 288 CTAGCCCCTACCCCCC 711 ATTAGG AATT  9525  9547 GCCCCTACCCCCCAATT 289 GCCCCTACCCCCCAAT 712 AGGAGG TAGG  9526  9548 CCCCTACCCCCCAATTA 290 CCCCTACCCCCCAATT 713 GGAGGG AGGA  9532  9554 CCCCCCAATTAGGAGGG 291 CCCCCCAATTAGGAGG 714 CACTGG GCAC  9543  9565 GGAGGGCACTGGCCCCC 292 GGAGGGCACTGGCCCC 715 AACAGG CAAC  9606  9628 ACATCCGTATTACTCGC 293 ACATCCGTATTACTCG 716 ATCAGG CATC  9692  9714 ACTGCTTATTACAATTT 294 ACTGCTTATTACAATT 717 TACTGG TTAC  9693  9715 CTGCTTATTACAATTTT 295 CTGCTTATTACAATTTT 718 ACTGGG ACT  9756  9778 TCTCCCTTCACCATTTCC 296 TCTCCCTTCACCATTTC 719 GACGG CGA  9765  9787 ACCATTTCCGACGGCAT 297 ACCATTTCCGACGGCA 720 CTACGG TCTA  9789  9811 TCAACATTTTTTGTAGC 298 TCAACATTTTTTGTAG 721 CACAGG CCAC  9798  9820 TTTGTAGCCACAGGCTT 299 TTTGTAGCCACAGGCT 722 CCACGG TCCA  9816  9838 CACGGACTTCACGTCAT 300 CACGGACTTCACGTCA 723 TATTGG TTAT  9885  9907 TTTACATCCAAACATCA 301 TTTACATCCAAACATC 724 CTTTGG ACTT  9910  9932 TCGAAGCCGCCGCCTGA 302 TCGAAGCCGCCGCCTG 725 TACTGG ATAC  9926  9948 ATACTGGCATTTTGTAG 303 ATACTGGCATTTTGTA 726 ATGTGG GATG  9963  9985 TATGTCTCCATCTATTG 304 TATGTCTCCATCTATT 727 ATGAGG GATG  9964  9986 ATGTCTCCATCTATTGA 305 ATGTCTCCATCTATTG 728 TGAGGG ATGA 10122 10144 TTTTGACTACCACAACT 306 TTTTGACTACCACAAC 729 CAACGG TCAA 10155 10177 AAATCCACCCCTTACGA 307 AAATCCACCCCTTACG 730 GTGCGG AGTG 10343 10365 CATCATCCTAGCCCTAA 308 CATCATCCTAGCCCTA 731 GTCTGG AGTC 10365 10387 GCCTATGAGTGACTACA 309 GCCTATGAGTGACTAC 732 AAAAGG AAAA 10385 10407 AGGATTAGACTGAACCG 310 AGGATTAGACTGAACC 733 AATTGG GAAT 10500 10522 GCATTTACCATCTCACT 311 GCATTTACCATCTCAC 734 TCTAGG TTCT 10551 10573 TCCTCCCTACTATGCCT 312 TCCTCCCTACTATGCC 735 AGAAGG TAGA 10664 10686 CTTTGCCGCCTGCGAAG 313 CTTTGCCGCCTGCGAA 736 CAGCGG GCAG 10667 10689 TGCCGCCTGCGAAGCAG 314 TGCCGCCTGCGAAGCA 737 CGGTGG GCGG 10668 10690 GCCGCCTGCGAAGCAGC 315 GCCGCCTGCGAAGCAG 738 GGTGGG CGGT 10704 10726 GTCTCAATCTCCAACAC 316 GTCTCAATCTCCAACA 739 ATATGG CATA 10972 10994 ACTCCTACCCCTCACAA 317 ACTCCTACCCCTCACA 740 TCATGG ATCA 11128 11150 AACCACACTTATCCCCA 318 AACCACACTTATCCCC 741 CCTTGG ACCT 11147 11169 TTGGCTATCATCACCCG 319 TTGGCTATCATCACCC 742 ATGAGG GATG 11174 11196 CAGCCAGAACGCCTGA 320 CAGCCAGAACGCCTGA 743 ACGCAGG ACGC 11204 11226 TTCCTATTCTACACCCT 321 TTCCTATTCTACACCCT 744 AGTAGG AGT 11252 11274 ATTTACACTCACAACAC 322 ATTTACACTCACAACA 745 CCTAGG CCCT 11369 11391 ATAGTAAAGATACCTCT 323 ATAGTAAAGATACCTC 746 TTACGG TTTA 11417 11439 CATGTCGAAGCCCCCAT 324 CATGTCGAAGCCCCCA 747 CGCTGG TCGC 11418 11440 ATGTCGAAGCCCCCATC 325 ATGTCGAAGCCCCCAT 748 GCTGGG CGCT 11453 11475 GCCGCAGTACTCTTAAA 326 GCCGCAGTACTCTTAA 749 ACTAGG AACT 11456 11478 GCAGTACTCTTAAAACT 327 GCAGTACTCTTAAAAC 750 AGGCGG TAGG 11462 11484 CTCTTAAAACTAGGCGG 328 CTCTTAAAACTAGGCG 751 CTATGG GCTA 11540 11562 TTCCTTGTACTATCCCTA 329 TTCCTTGTACTATCCCT 752 TGAGG ATG 11669 11691 CAAACCCCCTGAAGCTT 330 CAAACCCCCTGAAGCT 753 CACCGG TCAC 11696 11718 GTCATTCTCATAATCGC 331 GTCATTCTCATAATCG 754 CCACGG CCCA 11697 11719 TCATTCTCATAATCGCC 332 TCATTCTCATAATCGC 755 CACGGG CCAC 11777 11799 CGCATCATAATCCTCTC 333 CGCATCATAATCCTCT 756 TCAAGG CTCA 11866 11888 ACCCCCCACTATTAACC 334 ACCCCCCACTATTAAC 757 TACTGG CTAC 11867 11889 CCCCCCACTATTAACCT 335 CCCCCCACTATTAACC 758 ACTGGG TACT 11927 11949 AATATCACTCTCCTACT 336 AATATCACTCTCCTAC 759 TACAGG TTAC 11985 12007 ACATATTTACCACAACA 337 ACATATTTACCACAAC 760 CAATGG ACAA 11986 12008 CATATTTACCACAACAC 338 CATATTTACCACAACA 761 AATGGG CAAT 11987 12009 ATATTTACCACAACACA 339 ATATTTACCACAACAC 762 ATGGGG AATG 12104 12126 CTCAACCCCGACATCAT 340 CTCAACCCCGACATCA 763 TACCGG TTAC 12105 12127 TCAACCCCGACATCATT 341 TCAACCCCGACATCAT 764 ACCGGG TACC 12164 12186 GATTGTGAATCTGACAA 342 GATTGTGAATCTGACA 765 CAGAGG ACAG 12235 12257 TGCCCCCATGTCTAACA 343 TGCCCCCATGTCTAAC 766 ACATGG AACA 12254 12276 ATGGCTTTCTCAACTTTT 344 ATGGCTTTCTCAACTT 767 AAAGG TTAA 12272 12294 AAAGGATAACAGCTATC 345 AAAGGATAACAGCTAT 768 CATTGG CCAT 12279 12301 AACAGCTATCCATTGGT 346 AACAGCTATCCATTGG 769 CTTAGG TCTT 12294 12316 GTCTTAGGCCCCAAAAA 347 GTCTTAGGCCCCAAAA 770 TTTTGG ATTT 12608 12630 CTGTAGCATTGTTCGTT 348 CTGTAGCATTGTTCGT 771 ACATGG TACA 12742 12764 AACCTATTCCAACTGTT 349 AACCTATTCCAACTGT 772 CATCGG TCAT 12750 12772 CCAACTGTTCATCGGCT 350 CCAACTGTTCATCGGC 773 GAGAGG TGAG 12751 12773 CAACTGTTCATCGGCTG 351 CAACTGTTCATCGGCT 774 AGAGGG GAGA 12757 12779 TTCATCGGCTGAGAGGG 352 TTCATCGGCTGAGAGG 775 CGTAGG GCGT 12847 12869 GCAATCCTATACAACCG 353 GCAATCCTATACAACC 776 TATCGG GTAT 12856 12878 TACAACCGTATCGGCGA 354 TACAACCGTATCGGCG 777 TATCGG ATAT 12958 12980 CCAAGCCTCACCCCACT 355 CCAAGCCTCACCCCAC 778 ACTAGG TACT 12979 13001 GGCCTCCTCCTAGCAGC 356 GGCCTCCTCCTAGCAG 779 AGCAGG CAGC 12997 13019 GCAGGCAAATCAGCCC 357 GCAGGCAAATCAGCCC 780 AATTAGG AATT 13030 13052 TGACTCCCCTCAGCCAT 358 TGACTCCCCTCAGCCA 781 AGAAGG TAGA 13081 13103 TCAAGCACTATAGTTGT 359 TCAAGCACTATAGTTG 782 AGCAGG TAGC 13156 13178 CAAACTCTAACACTATG 360 CAAACTCTAACACTAT 783 CTTAGG GCTT 13246 13268 TTCTCCACTTCAAGTCA 361 TTCTCCACTTCAAGTC 784 ACTAGG AACT 13267 13289 GGACTCATAATAGTTAC 362 GGACTCATAATAGTTA 785 AATCGG CAAT 13345 13367 GCCATACTATTTATGTG 363 GCCATACTATTTATGT 786 CTCCGG GCTC 13346 13368 CCATACTATTTATGTGC 364 CCATACTATTTATGTG 787 TCCGGG CTCC 13393 13415 GAACAAGATATTCGAA 365 GAACAAGATATTCGAA 788 AAATAGG AAAT 13396 13418 CAAGATATTCGAAAAAT 366 CAAGATATTCGAAAAA 789 AGGAGG TAGG 13441 13463 ACTTCAACCTCCCTCAC 367 ACTTCAACCTCCCTCA 790 CATTGG CCAT 13459 13481 ATTGGCAGCCTAGCATT 368 ATTGGCAGCCTAGCAT 791 AGCAGG TAGC 13477 13499 GCAGGAATACCTTTCCT 369 GCAGGAATACCTTTCC 792 CACAGG TCAC 13612 13634 ATAATTCTTCTCACCCT 370 ATAATTCTTCTCACCC 793 AACAGG TAAC 13686 13708 ACTAAACCCCATTAAAC 371 ACTAAACCCCATTAAA 794 GCCTGG CGCC 13693 13715 CCCATTAAACGCCTGGC 372 CCCATTAAACGCCTGG 795 AGCCGG CAGC 13708 13730 GCAGCCGGAAGCCTATT 373 GCAGCCGGAAGCCTAT 796 CGCAGG TCGC 13804 13826 GCCCTCGCTGTCACTTT 374 GCCCTCGCTGTCACTT 797 CCTAGG TCCT 13894 13916 TTTTATTTCTCCAACATA 375 TTTTATTTCTCCAACAT 798 CTCGG ACT 13936 13958 CACCGCACAATCCCCTA 376 CACCGCACAATCCCCT 799 TCTAGG ATCT 14059 14081 ATCATCACCTCAACCCA 377 ATCATCACCTCAACCC 800 AAAAGG AAAA 14237 14259 TACAAAGCCCCCGCACC 378 TACAAAGCCCCCGCAC 801 AATAGG CAAT 14417 14439 ACCCCTGACCCCCATGC 379 ACCCCTGACCCCCATG 802 CTCAGG CCTC 14579 14601 AATACTAAACCCCCATA 380 AATACTAAACCCCCAT 803 AATAGG AAAT 14585 14607 AAACCCCCATAAATAGG 381 AAACCCCCATAAATAG 804 AGAAGG GAGA 14664 14686 CATACATCATTATTCTC 382 CATACATCATTATTCT 805 GCACGG CGCA 14825 14847 ATCTCCGCATGATGAAA 383 ATCTCCGCATGATGAA 806 CTTCGG ACTT 14837 14859 TGAAACTTCGGCTCACT 384 TGAAACTTCGGCTCAC 807 CCTTGG TCCT 14867 14889 CTGATCCTCCAAATCAC 385 CTGATCCTCCAAATCA 808 CACAGG CCAC 14951 14973 ATCACTCGAGACGTAAA 386 ATCACTCGAGACGTAA 809 TTATGG ATTA 14981 15003 ATCCGCTACCTTCACGC 387 ATCCGCTACCTTCACG 810 CAATGG CCAA 15020 15042 ATCTGCCTCTTCCTACA 388 ATCTGCCTCTTCCTAC 811 CATCGG ACAT 15021 15043 TCTGCCTCTTCCTACAC 389 TCTGCCTCTTCCTACA 812 ATCGGG CATC 15026 15048 CTCTTCCTACACATCGG 390 CTCTTCCTACACATCG 813 GCGAGG GGCG 15038 15060 ATCGGGCGAGGCCTATA 391 ATCGGGCGAGGCCTAT 814 TTACGG ATTA 15071 15093 TACTCAGAAACCTGAAA 392 TACTCAGAAACCTGAA 815 CATCGG ACAT 15113 15135 ACTATAGCAACAGCCTT 393 ACTATAGCAACAGCCT 816 CATAGG TCAT 15131 15153 ATAGGCTATGTCCTCCC 394 ATAGGCTATGTCCTCC 817 GTGAGG CGTG 15149 15171 TGAGGCCAAATATCATT 395 TGAGGCCAAATATCAT 818 CTGAGG TCTG 15150 15172 GAGGCCAAATATCATTC 396 GAGGCCAAATATCATT 819 TGAGGG CTGA 15151 15173 AGGCCAAATATCATTCT 397 AGGCCAAATATCATTC 820 GAGGGG TGAG 15194 15216 CTATCCGCCATCCCATA 398 CTATCCGCCATCCCAT 821 CATTGG ACAT 15195 15217 TATCCGCCATCCCATAC 399 TATCCGCCATCCCATA 822 ATTGGG CATT 15221 15243 GACCTAGTTCAATGAAT 400 GACCTAGTTCAATGAA 823 CTGAGG TCTG 15224 15246 CTAGTTCAATGAATCTG 401 CTAGTTCAATGAATCT 824 AGGAGG GAGG 15334 15356 CCTCCTATTCTTGCACG 402 CCTCCTATTCTTGCAC 825 AAACGG GAAA 15335 15357 CTCCTATTCTTGCACGA 403 CTCCTATTCTTGCACG 826 AACGGG AAAC 15353 15375 ACGGGATCAAACAACC 404 ACGGGATCAAACAAC 827 CCCTAGG CCCCT 15416 15438 TACACAATCAAAGACGC 405 TACACAATCAAAGACG 828 CCTCGG CCCT 15476 15498 CTATTCTCACCAGACCT 406 CTATTCTCACCAGACC 829 CCTAGG TCCT 15590 15612 CGATCCGTCCCTAACAA 407 CGATCCGTCCCTAACA 830 ACTAGG AACT 15593 15615 TCCGTCCCTAACAAACT 408 TCCGTCCCTAACAAAC 831 AGGAGG TAGG 15740 15762 CTCCTCATTCTAACCTG 409 CTCCTCATTCTAACCT 832 AATCGG GAAT 15743 15765 CTCATTCTAACCTGAAT 410 CTCATTCTAACCTGAA 833 CGGAGG TCGG 15776 15798 AGCTACCCTTTTACCAT 411 AGCTACCCTTTTACCA 834 CATTGG TCAT 15861 15883 TTGAAAACAAAATACTC 412 TTGAAAACAAAATACT 835 AAATGG CAAA 15862 15884 TGAAAACAAAATACTCA 413 TGAAAACAAAATACTC 836 AATGGG AAAT 15906 15928 AATACACCAGTCTTGTA 414 AATACACCAGTCTTGT 837 AACCGG AAAC 15928 15950 GAGATGAAAACCTTTTT 415 GAGATGAAAACCTTTT 838 CCAAGG TCCA 16012 16034 AACTATTCTCTGTTCTTT 416 AACTATTCTCTGTTCTT 839 CATGG TCA 16013 16035 ACTATTCTCTGTTCTTTC 417 ACTATTCTCTGTTCTTT 840 ATGGG CAT 16014 16036 CTATTCTCTGTTCTTTCA 418 CTATTCTCTGTTCTTTC 841 TGGGG ATG 16026 16048 CTTTCATGGGGAAGCAG 419 CTTTCATGGGGAAGCA 842 ATTTGG GATT 16027 16049 TTTCATGGGGAAGCAGA 420 TTTCATGGGGAAGCAG 843 TTTGGG ATTT 16108 16130 CAGCCACCATGAATATT 421 CAGCCACCATGAATAT 844 GTACGG TGTA 16252 16274 AAAGCCACCCCTCACCC 422 AAAGCCACCCCTCACC 845 ACTAGG CACT 16348 16370 CAAATCCCTTCTCGTCC 423 CAAATCCCTTCTCGTC 846 CCATGG CCCA 16367 16389 ATGGATGACCCCCCTCA 424 ATGGATGACCCCCCTC 847 GATAGG AGAT 16368 16390 TGGATGACCCCCCTCAG 425 TGGATGACCCCCCTCA 848 ATAGGG GATA 16369 16391 GGATGACCCCCCTCAGA 426 GGATGACCCCCCTCAG 849 TAGGGG ATAG 16434 16456 GAGTGCTACTCTCCTCG 427 GAGTGCTACTCTCCTC 850 CTCCGG GCTC 16435 16457 AGTGCTACTCTCCTCGC 428 AGTGCTACTCTCCTCG 851 TCCGGG CTCC 16449 16471 CGCTCCGGGCCCATAAC 429 CGCTCCGGGCCCATAA 852 ACTTGG CACT 16450 16472 GCTCCGGGCCCATAACA 430 GCTCCGGGCCCATAAC 853 CTTGGG ACTT 16451 16473 CTCCGGGCCCATAACAC 431 CTCCGGGCCCATAACA 854 TTGGGG CTTG 16452 16474 TCCGGGCCCATAACACT 432 TCCGGGCCCATAACAC 855 TGGGGG TTGG 16482 16504 AGTGAACTGTATCCGAC 433 AGTGAACTGTATCCGA 856 ATCTGG CATC 16495 16517 CGACATCTGGTTCCTAC 434 CGACATCTGGTTCCTA 857 TTCAGG CTTC 16496 16518 GACATCTGGTTCCTACT 435 GACATCTGGTTCCTAC 858 TCAGGG TTCA

TABLE 4 gRNA target sequence for human mtDNA carrying NGG sequence  on the (−) strand. nt sequence on the (+) strand containing CCN sequence followed Chr start Chr end by the reverse  20 nt gRNA target  position position complementary  SEQ sequence (will SEQ (+ (+ sequence of gRNA ID encode the gRNA ID strand) strand) target sequence NO targeting sequence) NO    17    39 CCCTATTAACCACTCAC  859 GCTCCCGTGAGTGGTT 2628 GGGAGC AATA    18    40 CCTATTAACCACTCACG  860 AGCTCCCGTGAGTGGT 2629 GGAGCT TAAT    26    48 CCACTCACGGGAGCTCT  861 GCATGGAGAGCTCCCG 2630 CCATGC TGAG    43    65 CCATGCATTTGGTATTT  862 AGACGAAAATACCAA 2631 TCGTCT ATGCA   104   126 CCGGAGCACCCTATGTC  863 TACTGCGACATAGGGT 2632 GCAGTA GCTC   112   134 CCCTATGTCGCAGTATC  864 AAGACAGATACTGCG 2633 TGTCTT ACATA   113   135 CCTATGTCGCAGTATCT  865 AAAGACAGATACTGC 2634 GTCTTT GACAT   140   162 CCTGCCTCATCCTATTA  866 GATAAATAATAGGATG 2635 TTTATC AGGC   144   166 CCTCATCCTATTATTTAT  867 GTGCGATAAATAATAG 2636 CGCAC GATG   150   172 CCTATTATTTATCGCAC  868 ACGTAGGTGCGATAAA 2637 CTACGT TAAT   166   188 CCTACGTTCAATATTAC  869 TCGCCTGTAATATTGA 2638 AGGCGA ACGT   261   283 CCACTTTCCACACAGAC  870 TATGATGTCTGTGTGG 2639 ATCATA AAAG   268   290 CCACACAGACATCATAA  871 TTTTTGTTATGATGTCT 2640 CAAAAA GTG   298   320 CCAAACCCCCCCTCCCC  872 GAAGCGGGGGAGGGG 2641 CGCTTC GGGTT   304   326 CCCCCCTCCCCCGCTTC  873 TGGCCAGAAGCGGGG 2642 TGGCCA GAGGG   305   327 CCCCCTCCCCCGCTTCT  874 GTGGCCAGAAGCGGG 2643 GGCCAC GGAGG   306   328 CCCCTCCCCCGCTTCTG  875 TGTGGCCAGAAGCGG 2644 GCCACA GGGAG   307   329 CCCTCCCCCGCTTCTGG  876 CTGTGGCCAGAAGCGG 2645 CCACAG GGGA   308   330 CCTCCCCCGCTTCTGGC  877 GCTGTGGCCAGAAGCG 2646 CACAGC GGGG   311   333 CCCCCGCTTCTGGCCAC  878 AGTGCTGTGGCCAGAA 2647 AGCACT GCGG   312   334 CCCCGCTTCTGGCCACA  879 AAGTGCTGTGGCCAGA 2648 GCACTT AGCG   313   335 CCCGCTTCTGGCCACAG  880 TAAGTGCTGTGGCCAG 2649 CACTTA AAGC   314   336 CCGCTTCTGGCCACAGC  881 TTAAGTGCTGTGGCCA 2650 ACTTAA GAAG   324   346 CCACAGCACTTAAACAC  882 AGAGATGTGTTTAAGT 2651 ATCTCT GCTG   348   370 CCAAACCCCAAAAACA  883 GGTTCTTTGTTTTTGGG 2652 AAGAACC GTT   353   375 CCCCAAAAACAAAGAA  884 GTTAGGGTTCTTTGTTT 2653 CCCTAAC TTG   354   376 CCCAAAAACAAAGAAC  885 TGTTAGGGTTCTTTGTT 2654 CCTAACA TTT   355   377 CCAAAAACAAAGAACC  886 GTGTTAGGGTTCTTTG 2655 CTAACAC TTTT   369   391 CCCTAACACCAGCCTAA  887 ATCTGGTTAGGCTGGT 2656 CCAGAT GTTA   370   392 CCTAACACCAGCCTAAC  888 AATCTGGTTAGGCTGG 2657 CAGATT TGTT   377   399 CCAGCCTAACCAGATTT  889 AATTTGAAATCTGGTT 2658 CAAATT AGGC   381   403 CCTAACCAGATTTCAAA  890 ATAAAATTTGAAATCT 2659 TTTTAT GGTT   386   408 CCAGATTTCAAATTTTA  891 AAAAGATAAAATTTGA 2660 TCTTTT AATC   433   455 CCCCCCAACTAACACAT  892 AAAATAATGTGTTAGT 2661 TATTTT TGGG   434   456 CCCCCAACTAACACATT  893 GAAAATAATGTGTTAG 2662 ATTTTC TTGG   435   457 CCCCAACTAACACATTA  894 GGAAAATAATGTGTTA 2663 TTTTCC GTTG   436   458 CCCAACTAACACATTAT  895 GGGAAAATAATGTGTT 2664 TTTCCC AGTT   437   459 CCAACTAACACATTATT  896 GGGGAAAATAATGTGT 2665 TTCCCC TAGT   456   478 CCCCTCCCACTCCCATA  897 TAGTAGTATGGGAGTG 2666 CTACTA GGAG   457   479 CCCTCCCACTCCCATAC  898 TTAGTAGTATGGGAGT 2667 TACTAA GGGA   458   480 CCTCCCACTCCCATACT  899 ATTAGTAGTATGGGAG 2668 ACTAAT TGGG   461   483 CCCACTCCCATACTACT  900 GAGATTAGTAGTATGG 2669 AATCTC GAGT   462   484 CCACTCCCATACTACTA  901 TGAGATTAGTAGTATG 2670 ATCTCA GGAG   467   489 CCCATACTACTAATCTC  902 ATTGATGAGATTAGTA 2671 ATCAAT GTAT   468   490 CCATACTACTAATCTCA  903 TATTGATGAGATTAGT 2672 TCAATA AGTA   494   516 CCCCCGCCCATCCTACC  904 GTGCTGGGTAGGATGG 2673 CAGCAC GCGG   495   517 CCCCGCCCATCCTACCC  905 TGTGCTGGGTAGGATG 2674 AGCACA GGCG   496   518 CCCGCCCATCCTACCCA  906 GTGTGCTGGGTAGGAT 2675 GCACAC GGGC   497   519 CCGCCCATCCTACCCAG  907 TGTGTGCTGGGTAGGA 2676 CACACA TGGG   500   522 CCCATCCTACCCAGCAC  908 GTGTGTGTGCTGGGTA 2677 ACACAC GGAT   501   523 CCATCCTACCCAGCACA  909 TGTGTGTGTGCTGGGT 2678 CACACA AGGA   505   527 CCTACCCAGCACACACA  910 GCGGTGTGTGTGTGCT 2679 CACCGC GGGT   509   531 CCCAGCACACACACACC  911 AGCAGCGGTGTGTGTG 2680 GCTGCT TGCT   510   532 CCAGCACACACACACCG  912 TAGCAGCGGTGTGTGT 2681 CTGCTA GTGC   524   546 CCGCTGCTAACCCCATA  913 TCGGGGTATGGGGTTA 2682 CCCCGA GCAG   534   556 CCCCATACCCCGAACCA  914 TTTGGTTGGTTCGGGG 2683 ACCAAA TATG   535   557 CCCATACCCCGAACCAA  915 GTTTGGTTGGTTCGGG 2684 CCAAAC GTAT   536   558 CCATACCCCGAACCAAC  916 GGTTTGGTTGGTTCGG 2685 CAAACC GGTA   541   563 CCCCGAACCAACCAAAC  917 TTTGGGGTTTGGTTGG 2686 CCCAAA TTCG   542   564 CCCGAACCAACCAAACC  918 CTTTGGGGTTTGGTTG 2687 CCAAAG GTTC   543   565 CCGAACCAACCAAACCC  919 TCTTTGGGGTTTGGTT 2688 CAAAGA GGTT   548   570 CCAACCAAACCCCAAA  920 GGGTGTCTTTGGGGTT 2689 GACACCC TGGT   552   574 CCAAACCCCAAAGACA  921 TGGGGGGTGTCTTTGG 2690 CCCCCCA GGTT   557   579 CCCCAAAGACACCCCCC  922 AACTGTGGGGGGTGTC 2691 ACAGTT TTTG   558   580 CCCAAAGACACCCCCCA  923 AAACTGTGGGGGGTGT 2692 CAGTTT CTTT   559   581 CCAAAGACACCCCCCAC  924 TAAACTGTGGGGGGTG 2693 AGTTTA TCTT   568   590 CCCCCCACAGTTTATGT  925 TAAGCTACATAAACTG 2694 AGCTTA TGGG   569   591 CCCCCACAGTTTATGTA  926 GTAAGCTACATAAACT 2695 GCTTAC GTGG   570   592 CCCCACAGTTTATGTAG  927 GGTAAGCTACATAAAC 2696 CTTACC TGTG   571   593 CCCACAGTTTATGTAGC  928 AGGTAAGCTACATAAA 2697 TTACCT CTGT   572   594 CCACAGTTTATGTAGCT  929 GAGGTAAGCTACATAA 2698 TACCTC ACTG   591   613 CCTCCTCAAAGCAATAC  930 TTCAGTGTATTGCTTT 2699 ACTGAA GAGG   594   616 CCTCAAAGCAATACACT  931 ATTTTCAGTGTATTGC 2700 GAAAAT TTTG   637   659 CCCCATAAACAAATAGG  932 ACCAAACCTATTTGTT 2701 TTTGGT TATG   638   660 CCCATAAACAAATAGGT  933 GACCAAACCTATTTGT 2702 TTGGTC TTAT   639   661 CCATAAACAAATAGGTT  934 GGACCAAACCTATTTG 2703 TGGTCC TTTA   660   682 CCTAGCCTTTCTATTAG  935 TAAGAGCTAATAGAA 2704 CTCTTA AGGCT   665   687 CCTTTCTATTAGCTCTTA  936 CTTACTAAGAGCTAAT 2705 GTAAG AGAA   705   727 CCCCGTTCCAGTGAGTT  937 AGGGTGAACTCACTGG 2706 CACCCT AACG   706   728 CCCGTTCCAGTGAGTTC  938 GAGGGTGAACTCACTG 2707 ACCCTC GAAC   707   729 CCGTTCCAGTGAGTTCA  939 AGAGGGTGAACTCACT 2708 CCCTCT GGAA   712   734 CCAGTGAGTTCACCCTC  940 GATTTAGAGGGTGAAC 2709 TAAATC TCAC   724   746 CCCTCTAAATCACCACG  941 TTTGATCGTGGTGATT 2710 ATCAAA TAGA   725   747 CCTCTAAATCACCACGA  942 TTTTGATCGTGGTGAT 2711 TCAAAA TTAG   736   758 CCACGATCAAAAGGAA  943 ATGCTTGTTCCTTTTGA 2712 CAAGCAT TCG   792   814 CCTAGCCACACCCCCAC  944 TTTCCCGTGGGGGTGT 2713 GGGAAA GGCT   797   819 CCACACCCCCACGGGAA  945 TGCTGTTTCCCGTGGG 2714 ACAGCA GGTG   802   824 CCCCCACGGGAAACAG  946 ATCACTGCTGTTTCCC 2715 CAGTGAT GTGG   803   825 CCCCACGGGAAACAGC  947 AATCACTGCTGTTTCC 2716 AGTGATT CGTG   804   826 CCCACGGGAAACAGCA  948 TAATCACTGCTGTTTC 2717 GTGATTA CCGT   805   827 CCACGGGAAACAGCAG  949 TTAATCACTGCTGTTT 2718 TGATTAA CCCG   828   850 CCTTTAGCAATAAACGA  950 AAACTTTCGTTTATTG 2719 AAGTTT CTAA   867   889 CCCCAGGGTTGGTCAAT  951 CACGAAATTGACCAAC 2720 TTCGTG CCTG   868   890 CCCAGGGTTGGTCAATT  952 GCACGAAATTGACCAA 2721 TCGTGC CCCT   869   891 CCAGGGTTGGTCAATTT  953 GGCACGAAATTGACCA 2722 CGTGCC ACCC   890   912 CCAGCCACCGCGGTCAC  954 AATCGTGTGACCGCGG 2723 ACGATT TGGC   894   916 CCACCGCGGTCACACGA  955 GGTTAATCGTGTGACC 2724 TTAACC GCGG   897   919 CCGCGGTCACACGATTA  956 TTGGGTTAATCGTGTG 2725 ACCCAA ACCG   915   937 CCCAAGTCAATAGAAGC  957 ACGCCGGCTTCTATTG 2726 CGGCGT ACTT   916   938 CCAAGTCAATAGAAGCC  958 TACGCCGGCTTCTATT 2727 GGCGTA GACT   931   953 CCGGCGTAAAGAGTGTT  959 ATCTAAAACACTCTTT 2728 TTAGAT ACGC   956   978 CCCCCTCCCCAATAAAG  960 TTTTAGCTTTATTGGG 2729 CTAAAA GAGG   957   979 CCCCTCCCCAATAAAGC  961 GTTTTAGCTTTATTGG 2730 TAAAAC GGAG   958   980 CCCTCCCCAATAAAGCT  962 AGTTTTAGCTTTATTG 2731 AAAACT GGGA   959   981 CCTCCCCAATAAAGCTA  963 GAGTTTTAGCTTTATT 2732 AAACTC GGGG   962   984 CCCCAATAAAGCTAAAA  964 GGTGAGTTTTAGCTTT 2733 CTCACC ATTG   963   985 CCCAATAAAGCTAAAAC  965 AGGTGAGTTTTAGCTT 2734 TCACCT TATT   964   986 CCAATAAAGCTAAAACT  966 CAGGTGAGTTTTAGCT 2735 CACCTG TTAT   983  1005 CCTGAGTTGTAAAAAAC  967 ACTGGAGTTTTTTACA 2736 TCCAGT ACTC  1001  1023 CCAGTTGACACAAAATA  968 GTAGTCTATTTTGTGT 2737 GACTAC CAAC  1064  1086 CCCAAACTGGGATTAGA  969 GGGGTATCTAATCCCA 2738 TACCCC GTTT  1065  1087 CCAAACTGGGATTAGAT  970 TGGGGTATCTAATCCC 2739 ACCCCA AGTT  1083  1105 CCCCACTATGCTTAGCC  971 GTTTAGGGCTAAGCAT 2740 CTAAAC AGTG  1084  1106 CCCACTATGCTTAGCCC  972 GGTTTAGGGCTAAGCA 2741 TAAACC TAGT  1085  1107 CCACTATGCTTAGCCCT  973 AGGTTTAGGGCTAAGC 2742 AAACCT ATAG  1098  1120 CCCTAAACCTCAACAGT  974 GATTTAACTGTTGAGG 2743 TAAATC TTTA  1099  1121 CCTAAACCTCAACAGTT  975 TGATTTAACTGTTGAG 2744 AAATCA GTTT  1105  1127 CCTCAACAGTTAAATCA  976 TTTTGTTGATTTAACTG 2745 ACAAAA TTG  1135  1157 CCAGAACACTACGAGCC  977 AGCTGTGGCTCGTAGT 2746 ACAGCT GTTC  1150  1172 CCACAGCTTAAAACTCA  978 GTCCTTTGAGTTTTAA 2747 AAGGAC GCTG  1172  1194 CCTGGCGGTGCTTCATA  979 GAGGGATATGAAGCA 2748 TCCCTC CCGCC  1190  1212 CCCTCTAGAGGAGCCTG  980 ACAGAACAGGCTCCTC 2749 TTCTGT TAGA  1191  1213 CCTCTAGAGGAGCCTGT  981 TACAGAACAGGCTCCT 2750 TCTGTA CTAG  1203  1225 CCTGTTCTGTAATCGAT  982 GGGTTTATCGATTACA 2751 AAACCC GAAC  1223  1245 CCCCGATCAACCTCACC  983 AGAGGTGGTGAGGTTG 2752 ACCTCT ATCG  1224  1246 CCCGATCAACCTCACCA  984 AAGAGGTGGTGAGGTT 2753 CCTCTT GATC  1225  1247 CCGATCAACCTCACCAC  985 CAAGAGGTGGTGAGG 2754 CTCTTG TTGAT  1233  1255 CCTCACCACCTCTTGCT  986 AGGCTGAGCAAGAGG 2755 CAGCCT TGGTG  1238  1260 CCACCTCTTGCTCAGCC  987 TATATAGGCTGAGCAA 2756 TATATA GAGG  1241  1263 CCTCTTGCTCAGCCTAT  988 CGGTATATAGGCTGAG 2757 ATACCG CAAG  1253  1275 CCTATATACCGCCATCT  989 TGCTGAAGATGGCGGT 2758 TCAGCA ATAT  1261  1283 CCGCCATCTTCAGCAAA  990 TCAGGGTTTGCTGAAG 2759 CCCTGA ATGG  1264  1286 CCATCTTCAGCAAACCC  991 TCATCAGGGTTTGCTG 2760 TGATGA AAGA  1278  1300 CCCTGATGAAGGCTACA  992 TTACTTTGTAGCCTTC 2761 AAGTAA ATCA  1279  1301 CCTGATGAAGGCTACAA  993 CTTACTTTGTAGCCTTC 2762 AGTAAG ATC  1310  1332 CCCACGTAAAGACGTTA  994 TTGACCTAACGTCTTT 2763 GGTCAA ACGT  1311  1333 CCACGTAAAGACGTTAG  995 CTTGACCTAACGTCTT 2764 GTCAAG TACG  1340  1362 CCCATGAGGTGGCAAG  996 CCCATTTCTTGCCACC 2765 AAATGGG TCAT  1341  1363 CCATGAGGTGGCAAGA  997 GCCCATTTCTTGCCAC 2766 AATGGGC CTCA  1375  1397 CCCCAGAAAACTACGAT  998 AGGGCTATCGTAGTTT 2767 AGCCCT TCTG  1376  1398 CCCAGAAAACTACGATA  999 AAGGGCTATCGTAGTT 2768 GCCCTT TTCT  1377  1399 CCAGAAAACTACGATA 1000 TAAGGGCTATCGTAGT 2769 GCCCTTA TTTC  1394  1416 CCCTTATGAAACTTAAG 1001 TCGACCCTTAAGTTTC 2770 GGTCGA ATAA  1395  1417 CCTTATGAAACTTAAGG 1002 TTCGACCCTTAAGTTT 2771 GTCGAA CATA  1465  1487 CCCTGAAGCGCGTACAC 1003 GGCGGTGTGTACGCGC 2772 ACCGCC TTCA  1466  1488 CCTGAAGCGCGTACACA 1004 GGGCGGTGTGTACGCG 2773 CCGCCC CTTC  1483  1505 CCGCCCGTCACCCTCCT 1005 TACTTGAGGAGGGTGA 2774 CAAGTA CGGG  1486  1508 CCCGTCACCCTCCTCAA 1006 GTATACTTGAGGAGGG 2775 GTATAC TGAC  1487  1509 CCGTCACCCTCCTCAAG 1007 AGTATACTTGAGGAGG 2776 TATACT GTGA  1493  1515 CCCTCCTCAAGTATACT 1008 CTTTGAAGTATACTTG 2777 TCAAAG AGGA  1494  1516 CCTCCTCAAGTATACTT 1009 CCTTTGAAGTATACTT 2778 CAAAGG GAGG  1497  1519 CCTCAAGTATACTTCAA 1010 TGTCCTTTGAAGTATA 2779 AGGACA CTTG  1531  1553 CCCCTACGCATTTATAT 1011 TCCTCTATATAAATGC 2780 AGAGGA GTAG  1532  1554 CCCTACGCATTTATATA 1012 CTCCTCTATATAAATG 2781 GAGGAG CGTA  1533  1555 CCTACGCATTTATATAG 1013 TCTCCTCTATATAAAT 2782 AGGAGA GCGT  1601  1623 CCAGAGTGTAGCTTAAC 1014 CTTTGTGTTAAGCTAC 2783 ACAAAG ACTC  1626  1648 CCCAACTTACACTTAGG 1015 AAATCTCCTAAGTGTA 2784 AGATTT AGTT  1627  1649 CCAACTTACACTTAGGA 1016 GAAATCTCCTAAGTGT 2785 GATTTC AAGT  1662  1684 CCGCTCTGAGCTAAACC 1017 GGGCTAGGTTTAGCTC 2786 TAGCCC AGAG  1677  1699 CCTAGCCCCAAACCCAC 1018 GGTGGAGTGGGTTTGG 2787 TCCACC GGCT  1682  1704 CCCCAAACCCACTCCAC 1019 AGTAAGGTGGAGTGG 2788 CTTACT GTTTG  1683  1705 CCCAAACCCACTCCACC 1020 TAGTAAGGTGGAGTGG 2789 TTACTA GTTT  1684  1706 CCAAACCCACTCCACCT 1021 GTAGTAAGGTGGAGTG 2790 TACTAC GGTT  1689  1711 CCCACTCCACCTTACTA 1022 GTCTGGTAGTAAGGTG 2791 CCAGAC GAGT  1690  1712 CCACTCCACCTTACTAC 1023 TGTCTGGTAGTAAGGT 2792 CAGACA GGAG  1695  1717 CCACCTTACTACCAGAC 1024 AAGGTTGTCTGGTAGT 2793 AACCTT AAGG  1698  1720 CCTTACTACCAGACAAC 1025 GCTAAGGTTGTCTGGT 2794 CTTAGC AGTA  1706  1728 CCAGACAACCTTAGCCA 1026 ATGGTTTGGCTAAGGT 2795 AACCAT TGTC  1714  1736 CCTTAGCCAAACCATTT 1027 TTGGGTAAATGGTTTG 2796 ACCCAA GCTA  1720  1742 CCAAACCATTTACCCAA 1028 CTTTATTTGGGTAAAT 2797 ATAAAG GGTT  1725  1747 CCATTTACCCAAATAAA 1029 CTATACTTTATTTGGG 2798 GTATAG TAAA  1732  1754 CCCAAATAAAGTATAGG 1030 CTATCGCCTATACTTT 2799 CGATAG ATTT  1733  1755 CCAAATAAAGTATAGGC 1031 TCTATCGCCTATACTTT 2800 GATAGA ATT  1764  1786 CCTGGCGCAATAGATAT 1032 GGTACTATATCTATTG 2801 AGTACC CGCC  1785  1807 CCGCAAGGGAAAGATG 1033 AATTTTTCATCTTTCCC 2802 AAAAATT TTG  1812  1834 CCAAGCATAATATAGCA 1034 AGTCCTTGCTATATTA 2803 AGGACT TGCT  1837  1859 CCCCTATACCTTCTGCA 1035 TCATTATGCAGAAGGT 2804 TAATGA ATAG  1838  1860 CCCTATACCTTCTGCAT 1036 TTCATTATGCAGAAGG 2805 AATGAA TATA  1839  1861 CCTATACCTTCTGCATA 1037 ATTCATTATGCAGAAG 2806 ATGAAT GTAT  1845  1867 CCTTCTGCATAATGAAT 1038 TAGTTAATTCATTATG 2807 TAACTA CAGA  1889  1911 CCAAAGCTAAGACCCCC 1039 GGTTTCGGGGGTCTTA 2808 GAAACC GCTT  1901  1923 CCCCCGAAACCAGACG 1040 GGTAGCTCGTCTGGTT 2809 AGCTACC TCGG  1902  1924 CCCCGAAACCAGACGA 1041 AGGTAGCTCGTCTGGT 2810 GCTACCT TTCG  1903  1925 CCCGAAACCAGACGAG 1042 TAGGTAGCTCGTCTGG 2811 CTACCTA TTTC  1904  1926 CCGAAACCAGACGAGC 1043 TTAGGTAGCTCGTCTG 2812 TACCTAA GTTT  1910  1932 CCAGACGAGCTACCTAA 1044 CTGTTCTTAGGTAGCT 2813 GAACAG CGTC  1922  1944 CCTAAGAACAGCTAAA 1045 GTGCTCTTTTAGCTGTT 2814 AGAGCAC CTT  1946  1968 CCCGTCTATGTAGCAAA 1046 CACTATTTTGCTACAT 2815 ATAGTG AGAC  1947  1969 CCGTCTATGTAGCAAAA 1047 CCACTATTTTGCTACA 2816 TAGTGG TAGA  1996  2018 CCTACCGAGCCTGGTGA 1048 CAGCTATCACCAGGCT 2817 TAGCTG CGGT  2000  2022 CCGAGCCTGGTGATAGC 1049 CAACCAGCTATCACCA 2818 TGGTTG GGCT  2005  2027 CCTGGTGATAGCTGGTT 1050 TTGGACAACCAGCTAT 2819 GTCCAA CACC  2024  2046 CCAAGATAGAATCTTAG 1051 GTTGAACTAAGATTCT 2820 TTCAAC ATCT  2057  2079 CCCACAGAACCCTCTAA 1052 GGGGATTTAGAGGGTT 2821 ATCCCC CTGT  2058  2080 CCACAGAACCCTCTAAA 1053 AGGGGATTTAGAGGGT 2822 TCCCCT TCTG  2066  2088 CCCTCTAAATCCCCTTG 1054 AATTTACAAGGGGATT 2823 TAAATT TAGA  2067  2089 CCTCTAAATCCCCTTGT 1055 AAATTTACAAGGGGAT 2824 AAATTT TTAG  2076  2098 CCCCTTGTAAATTTAAC 1056 CTAACAGTTAAATTTA 2825 TGTTAG CAAG  2077  2099 CCCTTGTAAATTTAACT 1057 ACTAACAGTTAAATTT 2826 GTTAGT ACAA  2078  2100 CCTTGTAAATTTAACTG 1058 GACTAACAGTTAAATT 2827 TTAGTC TACA  2100  2122 CCAAAGAGGAACAGCT 1059 TCCAAAGAGCTGTTCC 2828 CTTTGGA TCTT  2136  2158 CCTTGTAGAGAGAGTAA 1060 AATTTTTTACTCTCTCT 2829 AAAATT ACA  2164  2186 CCCATAGTAGGCCTAAA 1061 GCTGCTTTTAGGCCTA 2830 AGCAGC CTAT  2165  2187 CCATAGTAGGCCTAAAA 1062 GGCTGCTTTTAGGCCT 2831 GCAGCC ACTA  2175  2197 CCTAAAAGCAGCCACCA 1063 CTTAATTGGTGGCTGC 2832 ATTAAG TTTT  2186  2208 CCACCAATTAAGAAAGC 1064 TTGAACGCTTTCTTAA 2833 GTTCAA TTGG  2189  2211 CCAATTAAGAAAGCGTT 1065 AGCTTGAACGCTTTCT 2834 CAAGCT TAAT  2217  2239 CCCACTACCTAAAAAAT 1066 TTTGGGATTTTTTAGG 2835 CCCAAA TAGT  2218  2240 CCACTACCTAAAAAATC 1067 GTTTGGGATTTTTTAG 2836 CCAAAC GTAG  2224  2246 CCTAAAAAATCCCAAAC 1068 TTATATGTTTGGGATT 2837 ATATAA TTTT  2234  2256 CCCAAACATATAACTGA 1069 AGGAGTTCAGTTATAT 2838 ACTCCT GTTT  2235  2257 CCAAACATATAACTGAA 1070 GAGGAGTTCAGTTATA 2839 CTCCTC TGTT  2254  2276 CCTCACACCCAATTGGA 1071 GATTGGTCCAATTGGG 2840 CCAATC TGTG  2261  2283 CCCAATTGGACCAATCT 1072 GGTGATAGATTGGTCC 2841 ATCACC AATT  2262  2284 CCAATTGGACCAATCTA 1073 GGGTGATAGATTGGTC 2842 TCACCC CAAT  2271  2293 CCAATCTATCACCCTAT 1074 TCTTCTATAGGGTGAT 2843 AGAAGA AGAT  2282  2304 CCCTATAGAAGAACTAA 1075 CTAACATTAGTTCTTC 2844 TGTTAG TATA  2283  2305 CCTATAGAAGAACTAAT 1076 ACTAACATTAGTTCTT 2845 GTTAGT CTAT  2328  2350 CCTCCGCATAAGCCTGC 1077 TCTGACGCAGGCTTAT 2846 GTCAGA GCGG  2331  2353 CCGCATAAGCCTGCGTC 1078 TAATCTGACGCAGGCT 2847 AGATTA TATG  2340  2362 CCTGCGTCAGATTAAAA 1079 TCAGTGTTTTAATCTG 2848 CACTGA ACGC  2378  2400 CCCAATATCTACAATCA 1080 GTTGGTTGATTGTAGA 2849 ACCAAC TATT  2379  2401 CCAATATCTACAATCAA 1081 TGTTGGTTGATTGTAG 2850 CCAACA ATAT  2396  2418 CCAACAAGTCATTATTA 1082 TGAGGGTAATAATGAC 2851 CCCTCA TTGT  2413  2435 CCCTCACTGTCAACCCA 1083 CTGTGTTGGGTTGACA 2852 ACACAG GTGA  2414  2436 CCTCACTGTCAACCCAA 1084 CCTGTGTTGGGTTGAC 2853 CACAGG AGTG  2426  2448 CCCAACACAGGCATGCT 1085 CTTATGAGCATGCCTG 2854 CATAAG TGTT  2427  2449 CCAACACAGGCATGCTC 1086 CCTTATGAGCATGCCT 2855 ATAAGG GTGT  2488  2510 CCCCGCCTGTTTACCAA 1087 ATGTTTTTGGTAAACA 2856 AAACAT GGCG  2489  2511 CCCGCCTGTTTACCAAA 1088 GATGTTTTTGGTAAAC 2857 AACATC AGGC  2490  2512 CCGCCTGTTTACCAAAA 1089 TGATGTTTTTGGTAAA 2858 ACATCA CAGG  2493  2515 CCTGTTTACCAAAAACA 1090 AGGTGATGTTTTTGGT 2859 TCACCT AAAC  2501  2523 CCAAAAACATCACCTCT 1091 GATGCTAGAGGTGATG 2860 AGCATC TTTT  2513  2535 CCTCTAGCATCACCAGT 1092 TCTAATACTGGTGATG 2861 ATTAGA CTAG  2525  2547 CCAGTATTAGAGGCACC 1093 GCAGGCGGTGCCTCTA 2862 GCCTGC ATAC  2540  2562 CCGCCTGCCCAGTGACA 1094 AACATGTGTCACTGGG 2863 CATGTT CAGG  2543  2565 CCTGCCCAGTGACACAT 1095 TTAAACATGTGTCACT 2864 GTTTAA GGGC  2547  2569 CCCAGTGACACATGTTT 1096 GCCGTTAAACATGTGT 2865 AACGGC CACT  2548  2570 CCAGTGACACATGTTTA 1097 GGCCGTTAAACATGTG 2866 ACGGCC TCAC  2569  2591 CCGCGGTACCCTAACCG 1098 TTTGCACGGTTAGGGT 2867 TGCAAA ACCG  2577  2599 CCCTAACCGTGCAAAGG 1099 ATGCTACCTTTGCACG 2868 TAGCAT GTTA  2578  2600 CCTAACCGTGCAAAGGT 1100 TATGCTACCTTTGCAC 2869 AGCATA GGTT  2583  2605 CCGTGCAAAGGTAGCAT 1101 GTGATTATGCTACCTT 2870 AATCAC TGCA  2611  2633 CCTTAAATAGGGACCTG 1102 TTCATACAGGTCCCTA 2871 TATGAA TTTA  2624  2646 CCTGTATGAATGGCTCC 1103 CCTCGTGGAGCCATTC 2872 ACGAGG ATAC  2639  2661 CCACGAGGGTTCAGCTG 1104 AAGAGACAGCTGAAC 2873 TCTCTT CCTCG  2670  2692 CCAGTGAAATTGACCTG 1105 CACGGGCAGGTCAATT 2874 CCCGTG TCAC  2683  2705 CCTGCCCGTGAAGAGGC 1106 ATGCCCGCCTCTTCAC 2875 GGGCAT GGGC  2687  2709 CCCGTGAAGAGGCGGG 1107 TGTTATGCCCGCCTCT 2876 CATAACA TCAC  2688  2710 CCGTGAAGAGGCGGGC 1108 GTGTTATGCCCGCCTC 2877 ATAACAC TTCA  2726  2748 CCCTATGGAGCTTTAAT 1109 TAATAAATTAAAGCTC 2878 TTATTA CATA  2727  2749 CCTATGGAGCTTTAATT 1110 TTAATAAATTAAAGCT 2879 TATTAA CCAT  2761  2783 CCTAACAAACCCACAGG 1111 TTAGGACCTGTGGGTT 2880 TCCTAA TGTT  2770  2792 CCCACAGGTCCTAAACT 1112 TTTGGTAGTTTAGGAC 2881 ACCAAA CTGT  2771  2793 CCACAGGTCCTAAACTA 1113 GTTTGGTAGTTTAGGA 2882 CCAAAC CCTG  2779  2801 CCTAAACTACCAAACCT 1114 TAATGCAGGTTTGGTA 2883 GCATTA GTTT  2788  2810 CCAAACCTGCATTAAAA 1115 CGAAATTTTTAATGCA 2884 ATTTCG GGTT  2793  2815 CCTGCATTAAAAATTTC 1116 CCAACCGAAATTTTTA 2885 GGTTGG ATGC  2821  2843 CCTCGGAGCAGAACCCA 1117 GGAGGTTGGGTTCTGC 2886 ACCTCC TCCG  2834  2856 CCCAACCTCCGAGCAGT 1118 GCATGTACTGCTCGGA 2887 ACATGC GGTT  2835  2857 CCAACCTCCGAGCAGTA 1119 AGCATGTACTGCTCGG 2888 CATGCT AGGT  2839  2861 CCTCCGAGCAGTACATG 1120 TCTTAGCATGTACTGC 2889 CTAAGA TCGG  2842  2864 CCGAGCAGTACATGCTA 1121 AAGTCTTAGCATGTAC 2890 AGACTT TGCT  2867  2889 CCAGTCAAAGCGAACTA 1122 GTATAGTAGTTCGCTT 2891 CTATAC TGAC  2899  2921 CCAATAACTTGACCAAC 1123 TGTTCCGTTGGTCAAG 2892 GGAACA TTAT  2911  2933 CCAACGGAACAAGTTAC 1124 CCTAGGGTAACTTGTT 2893 CCTAGG CCGT  2927  2949 CCCTAGGGATAACAGCG 1125 GGATTGCGCTGTTATC 2894 CAATCC CCTA  2928  2950 CCTAGGGATAACAGCGC 1126 AGGATTGCGCTGTTAT 2895 AATCCT CCCT  2948  2970 CCTATTCTAGAGTCCAT 1127 GTTGATATGGACTCTA 2896 ATCAAC GAAT  2961  2983 CCATATCAACAATAGGG 1128 CGTAAACCCTATTGTT 2897 TTTACG GATA  2985  3007 CCTCGATGTTGGATCAG 1129 GATGTCCTGATCCAAC 2898 GACATC ATCG  3007  3029 CCCGATGGTGCAGCCGC 1130 TTAATAGCGGCTGCAC 2899 TATTAA CATC  3008  3030 CCGATGGTGCAGCCGCT 1131 TTTAATAGCGGCTGCA 2900 ATTAAA CCAT  3020  3042 CCGCTATTAAAGGTTCG 1132 AACAAACGAACCTTTA 2901 TTTGTT ATAG  3056  3078 CCTACGTGATCTGAGTT 1133 GGTCTGAACTCAGATC 2902 CAGACC ACGT  3077  3099 CCGGAGTAATCCAGGTC 1134 GAAACCGACCTGGATT 2903 GGTTTC ACTC  3087  3109 CCAGGTCGGTTTCTATC 1135 AANGTAGATAGAAAC 2904 TACNTT CGACC  3116  3138 CCTCCCTGTACGAAAGG 1136 TCTTGTCCTTTCGTACA 2905 ACAAGA GGG  3119  3141 CCCTGTACGAAAGGACA 1137 TTCTCTTGTCCTTTCGT 2906 AGAGAA ACA  3120  3142 CCTGTACGAAAGGACA 1138 TTTCTCTTGTCCTTTCG 2907 AGAGAAA TAC  3148  3170 CCTACTTCACAAAGCGC 1139 GGGAAGGCGCTTTGTG 2908 CTTCCC AAGT  3164  3186 CCTTCCCCCGTAAATGA 1140 ATGATATCATTTACGG 2909 TATCAT GGGA  3168  3190 CCCCCGTAAATGATATC 1141 TGAGATGATATCATTT 2910 ATCTCA ACGG  3169  3191 CCCCGTAAATGATATCA 1142 TTGAGATGATATCATT 2911 TCTCAA TACG  3170  3192 CCCGTAAATGATATCAT 1143 GTTGAGATGATATCAT 2912 CTCAAC TTAC  3171  3193 CCGTAAATGATATCATC 1144 AGTTGAGATGATATCA 2913 TCAACT TTTA  3204  3226 CCCACACCCACCCAAGA 1145 CCCTGTTCTTGGGTGG 2914 ACAGGG GTGT  3205  3227 CCACACCCACCCAAGAA 1146 ACCCTGTTCTTGGGTG 2915 CAGGGT GGTG  3210  3232 CCCACCCAAGAACAGG 1147 AACAAACCCTGTTCTT 2916 GTTTGTT GGGT  3211  3233 CCACCCAAGAACAGGG 1148 TAACAAACCCTGTTCT 2917 TTTGTTA TGGG  3214  3236 CCCAAGAACAGGGTTTG 1149 TCTTAACAAACCCTGT 2918 TTAAGA TCTT  3215  3237 CCAAGAACAGGGTTTGT 1150 ATCTTAACAAACCCTG 2919 TAAGAT TTCT  3245  3267 CCCGGTAATCGCATAAA 1151 TTAAGTTTTATGCGAT 2920 ACTTAA TACC  3246  3268 CCGGTAATCGCATAAAA 1152 TTAAGTTTTATGCGA 2921 CTTAAA TTAC  3292  3314 CCTCTTCTTAACAACAT 1153 ATGGGTATGTTGTTAA 2922 ACCCAT GAAG  3310  3332 CCCATGGCCAACCTCCT 1154 AGGAGTAGGAGGTTG 2923 ACTCCT GCCAT  3311  3333 CCATGGCCAACCTCCTA 1155 GAGGAGTAGGAGGTT 2924 CTCCTC GGCCA  3317  3339 CCAACCTCCTACTCCTC 1156 TACAATGAGGAGTAG 2925 ATTGTA GAGGT  3321  3343 CCTCCTACTCCTCATTGT 1157 TGGGTACAATGAGGA 2926 ACCCA GTAGG  3324  3346 CCTACTCCTCATTGTAC 1158 GAATGGGTACAATGA 2927 CCATTC GGAGT  3330  3352 CCTCATTGTACCCATTC 1159 CGATTAGAATGGGTAC 2928 TAATCG AATG  3340  3362 CCCATTCTAATCGCAAT 1160 AATGCCATTGCGATTA 2929 GGCATT GAAT  3341  3363 CCATTCTAATCGCAATG 1161 GAATGCCATTGCGATT 2930 GCATTC AGAA  3363  3385 CCTAATGCTTACCGAAC 1162 TTTTTCGTTCGGTAAG 2931 GAAAAA CATT  3374  3396 CCGAACGAAAAATTCTA 1163 ATAGCCTAGAATTTTT 2932 GGCTAT CGTT  3414  3436 CCCCAACGTTGTAGGCC 1164 CGTAGGGGCCTACAAC 2933 CCTACG GTTG  3415  3437 CCCAACGTTGTAGGCCC 1165 CCGTAGGGGCCTACAA 2934 CTACGG CGTT  3416  3438 CCAACGTTGTAGGCCCC 1166 CCCGTAGGGGCCTACA 2935 TACGGG ACGT  3429  3451 CCCCTACGGGCTACTAC 1167 AGGGTTGTAGTAGCCC 2936 AACCCT GTAG  3430  3452 CCCTACGGGCTACTACA 1168 AAGGGTTGTAGTAGCC 2937 ACCCTT CGTA  3431  3453 CCTACGGGCTACTACAA 1169 GAAGGGTTGTAGTAGC 2938 CCCTTC CCGT  3448  3470 CCCTTCGCTGACGCCAT 1170 AGTTTTATGGCGTCAG 2939 AAAACT CGAA  3449  3471 CCTTCGCTGACGCCATA 1171 GAGTTTTATGGCGTCA 2940 AAACTC GCGA  3461  3483 CCATAAAACTCTTCACC 1172 CTCTTTGGTGAAGAGT 2941 AAAGAG TTTA  3476  3498 CCAAAGAGCCCCTAAA 1173 GGCGGGTTTTAGGGGC 2942 ACCCGCC TCTT  3484  3506 CCCCTAAAACCCGCCAC 1174 GTAGATGTGGCGGGTT 2943 ATCTAC TTAG  3485  3507 CCCTAAAACCCGCCACA 1175 GGTAGATGTGGCGGGT 2944 TCTACC TTTA  3486  3508 CCTAAAACCCGCCACAT 1176 TGGTAGATGTGGCGGG 2945 CTACCA TTTT  3493  3515 CCCGCCACATCTACCAT 1177 AGGGTGATGGTAGATG 2946 CACCCT TGGC  3494  3516 CCGCCACATCTACCATC 1178 GAGGGTGATGGTAGAT 2947 ACCCTC GTGG  3497  3519 CCACATCTACCATCACC 1179 GTAGAGGGTGATGGTA 2948 CTCTAC GATG  3506  3528 CCATCACCCTCTACATC 1180 GGCGGTGATGTAGAG 2949 ACCGCC GGTGA  3512  3534 CCCTCTACATCACCGCC 1181 GGTCGGGGCGGTGATG 2950 CCGACC TAGA  3513  3535 CCTCTACATCACCGCCC 1182 AGGTCGGGGCGGTGAT 2951 CGACCT GTAG  3524  3546 CCGCCCCGACCTTAGCT 1183 GGTGAGAGCTAAGGTC 2952 CTCACC GGGG  3527  3549 CCCCGACCTTAGCTCTC 1184 GATGGTGAGAGCTAA 2953 ACCATC GGTCG  3528  3550 CCCGACCTTAGCTCTCA 1185 CGATGGTGAGAGCTAA 2954 CCATCG GGTC  3529  3551 CCGACCTTAGCTCTCAC 1186 GCGATGGTGAGAGCTA 2955 CATCGC AGGT  3533  3555 CCTTAGCTCTCACCATC 1187 AAGAGCGATGGTGAG 2956 GCTCTT AGCTA  3545  3567 CCATCGCTCTTCTACTA 1188 GGTTCATAGTAGAAGA 2957 TGAACC GCGA  3566  3588 CCCCCCTCCCCATACCC 1189 GGGGTTGGGTATGGGG 2958 AACCCC AGGG  3567  3589 CCCCCTCCCCATACCCA 1190 GGGGGTTGGGTATGGG 2959 ACCCCC GAGG  3568  3590 CCCCTCCCCATACCCAA 1191 AGGGGGTTGGGTATGG 2960 CCCCCT GGAG  3569  3591 CCCTCCCCATACCCAAC 1192 CAGGGGGTTGGGTATG 2961 CCCCTG GGGA  3570  3592 CCTCCCCATACCCAACC 1193 CCAGGGGGTTGGGTAT 2962 CCCTGG GGGG  3573  3595 CCCCATACCCAACCCCC 1194 TGACCAGGGGGTTGGG 2963 TGGTCA TATG  3574  3596 CCCATACCCAACCCCCT 1195 TTGACCAGGGGGTTGG 2964 GGTCAA GTAT  3575  3597 CCATACCCAACCCCCTG 1196 GTTGACCAGGGGGTTG 2965 GTCAAC GGTA  3580  3602 CCCAACCCCCTGGTCAA 1197 TTGAGGTTGACCAGGG 2966 CCTCAA GGTT  3581  3603 CCAACCCCCTGGTCAAC 1198 GTTGAGGTTGACCAGG 2967 CTCAAC GGGT  3585  3607 CCCCCTGGTCAACCTCA 1199 CTAGGTTGAGGTTGAC 2968 ACCTAG CAGG  3586  3608 CCCCTGGTCAACCTCAA 1200 CCTAGGTTGAGGTTGA 2969 CCTAGG CCAG  3587  3609 CCCTGGTCAACCTCAAC 1201 GCCTAGGTTGAGGTTG 2970 CTAGGC ACCA  3588  3610 CCTGGTCAACCTCAACC 1202 GGCCTAGGTTGAGGTT 2971 TAGGCC GACC  3597  3619 CCTCAACCTAGGCCTCC 1203 TAAATAGGAGGCCTAG 2972 TATTTA GTTG  3603  3625 CCTAGGCCTCCTATTTA 1204 CTAGAATAAATAGGA 2973 TTCTAG GGCCT  3609  3631 CCTCCTATTTATTCTAGC 1205 AGGTGGCTAGAATAA 2974 CACCT ATAGG  3612  3634 CCTATTTATTCTAGCCA 1206 TAGAGGTGGCTAGAAT 2975 CCTCTA AAAT  3626  3648 CCACCTCTAGCCTAGCC 1207 GTAAACGGCTAGGCTA 2976 GTTTAC GAGG  3629  3651 CCTCTAGCCTAGCCGTT 1208 TGAGTAAACGGCTAGG 2977 TACTCA CTAG  3636  3658 CCTAGCCGTTTACTCAA 1209 AGAGGATTGAGTAAA 2978 TCCTCT CGGCT  3641  3663 CCGTTTACTCAATCCTC 1210 TGATCAGAGGATTGAG 2979 TGATCA TAAA  3654  3676 CCTCTGATCAGGGTGAG 1211 TTGATGCTCACCCTGA 2980 CATCAA TCAG  3689  3711 CCCTGATCGGCGCACTG 1212 TGCTCGCAGTGCGCCG 2981 CGAGCA ATCA  3690  3712 CCTGATCGGCGCACTGC 1213 CTGCTCGCAGTGCGCC 2982 GAGCAG GATC  3716  3738 CCCAAACAATCTCATAT 1214 GACTTCATATGAGATT 2983 GAAGTC GTTT  3717  3739 CCAAACAATCTCATATG 1215 TGACTTCATATGAGAT 2984 AAGTCA TGTT  3740  3762 CCCTAGCCATCATTCTA 1216 TGATAGTAGAATGATG 2985 CTATCA GCTA  3741  3763 CCTAGCCATCATTCTAC 1217 TTGATAGTAGAATGAT 2986 TATCAA GGCT  3746  3768 CCATCATTCTACTATCA 1218 TAATGTTGATAGTAGA 2987 ACATTA ATGA  3782  3804 CCTTTAACCTCTCCACC 1219 GATAAGGGTGGAGAG 2988 CTTATC GTTAA  3789  3811 CCTCTCCACCCTTATCA 1220 GTGTTGTGATAAGGGT 2989 CAACAC GGAG  3794  3816 CCACCCTTATCACAACA 1221 TTCTTGTGTTGTGATA 2990 CAAGAA AGGG  3797  3819 CCCTTATCACAACACAA 1222 GTGTTCTTGTGTTGTG 2991 GAACAC ATAA  3798  3820 CCTTATCACAACACAAG 1223 GGTGTTCTTGTGTTGT 2992 AACACC GATA  3819  3841 CCTCTGATTACTCCTGC 1224 ATGATGGCAGGAGTA 2993 CATCAT ATCAG  3831  3853 CCTGCCATCATGACCCT 1225 TGGCCAAGGGTCATGA 2994 TGGCCA TGGC  3835  3857 CCATCATGACCCTTGGC 1226 ATTATGGCCAAGGGTC 2995 CATAAT ATGA  3844  3866 CCCTTGGCCATAATATG 1227 ATAAATCATATTATGG 2996 ATTTAT CCAA  3845  3867 CCTTGGCCATAATATGA 1228 GATAAATCATATTATG 2997 TTTATC GCCA  3851  3873 CCATAATATGATTTATC 1229 TGTGGAGATAAATCAT 2998 TCCACA ATTA  3869  3891 CCACACTAGCAGAGACC 1230 TCGGTTGGTCTCTGCT 2999 AACCGA AGTG  3884  3906 CCAACCGAACCCCCTTC 1231 AAGGTCGAAGGGGGT 3000 GACCTT TCGGT  3888  3910 CCGAACCCCCTTCGACC 1232 CGGCAAGGTCGAAGG 3001 TTGCCG GGGTT  3893  3915 CCCCCTTCGACCTTGCC 1233 CCCTTCGGCAAGGTCG 3002 GAAGGG AAGG  3894  3916 CCCCTTCGACCTTGCCG 1234 CCCCTTCGGCAAGGTC 3003 AAGGGG GAAG  3895  3917 CCCTTCGACCTTGCCGA 1235 TCCCCTTCGGCAAGGT 3004 AGGGGA CGAA  3896  3918 CCTTCGACCTTGCCGAA 1236 CTCCCCTTCGGCAAGG 3005 GGGGAG TCGA  3903  3925 CCTTGCCGAAGGGGAGT 1237 GTTCGGACTCCCCTTC 3006 CCGAAC GGCA  3908  3930 CCGAAGGGGAGTCCGA 1238 GACTAGTTCGGACTCC 3007 ACTAGTC CCTT  3920  3942 CCGAACTAGTCTCAGGC 1239 GTTGAAGCCTGAGACT 3008 TTCAAC AGTT  3953  3975 CCGCAGGCCCCTTCGCC 1240 GAATAGGGCGAAGGG 3009 CTATTC GCCTG  3960  3982 CCCCTTCGCCCTATTCTT 1241 CTATGAAGAATAGGGC 3010 CATAG GAAG  3961  3983 CCCTTCGCCCTATTCTTC 1242 GCTATGAAGAATAGG 3011 ATAGC GCGAA  3962  3984 CCTTCGCCCTATTCTTCA 1243 GGCTATGAAGAATAG 3012 TAGCC GGCGA  3968  3990 CCCTATTCTTCATAGCC 1244 GTATTCGGCTATGAAG 3013 GAATAC AATA  3969  3991 CCTATTCTTCATAGCCG 1245 TGTATTCGGCTATGAA 3014 AATACA GAAT  3983  4005 CCGAATACACAAACATT 1246 TATAATAATGTTTGTG 3015 ATTATA TATT  4013  4035 CCCTCACCACTACAATC 1247 TAGGAAGATTGTAGTG 3016 TTCCTA GTGA  4014  4036 CCTCACCACTACAATCT 1248 CTAGGAAGATTGTAGT 3017 TCCTAG GGTG  4019  4041 CCACTACAATCTTCCTA 1249 TGTTCCTAGGAAGATT 3018 GGAACA GTAG  4032  4054 CCTAGGAACAACATATG 1250 GTGCGTCATATGTTGT 3019 ACGCAC TCCT  4058  4080 CCCCTGAACTCTACACA 1251 ATATGTTGTGTAGAGT 3020 ACATAT TCAG  4059  4081 CCCTGAACTCTACACAA 1252 AATATGTTGTGTAGAG 3021 CATATT TTCA  4060  4082 CCTGAACTCTACACAAC 1253 AAATATGTTGTGTAGA 3022 ATATTT GTTC  4088  4110 CCAAGACCCTACTTCTA 1254 GGAGGTTAGAAGTAG 3023 ACCTCC GGTCT  4094  4116 CCCTACTTCTAACCTCC 1255 GAACAGGGAGGTTAG 3024 CTGTTC AAGTA  4095  4117 CCTACTTCTAACCTCCC 1256 AGAACAGGGAGGTTA 3025 TGTTCT GAAGT  4106  4128 CCTCCCTGTTCTTATGA 1257 TCGAATTCATAAGAAC 3026 ATTCGA AGGG  4109  4131 CCCTGTTCTTATGAATT 1258 TGTTCGAATTCATAAG 3027 CGAACA AACA  4110  4132 CCTGTTCTTATGAATTC 1259 CTGTTCGAATTCATAA 3028 GAACAG GAAC  4137  4159 CCCCCGATTCCGCTACG 1260 GTTGGTCGTAGCGGAA 3029 ACCAAC TCGG  4138  4160 CCCCGATTCCGCTACGA 1261 AGTTGGTCGTAGCGGA 3030 CCAACT ATCG  4139  4161 CCCGATTCCGCTACGAC 1262 GAGTTGGTCGTAGCGG 3031 CAACTC AATC  4140  4162 CCGATTCCGCTACGACC 1263 TGAGTTGGTCGTAGCG 3032 AACTCA GAAT  4146  4168 CCGCTACGACCAACTCA 1264 GGTGTATGAGTTGGTC 3033 TACACC GTAG  4155  4177 CCAACTCATACACCTCC 1265 TTCATAGGAGGTGTAT 3034 TATGAA GAGT  4167  4189 CCTCCTATGAAAAAACT 1266 GTAGGAAGTTTTTTCA 3035 TCCTAC TAGG  4170  4192 CCTATGAAAAAACTTCC 1267 GTGGTAGGAAGTTTTT 3036 TACCAC TCAT  4185  4207 CCTACCACTCACCCTAG 1268 GTAATGCTAGGGTGAG 3037 CATTAC TGGT  4189  4211 CCACTCACCCTAGCATT 1269 ATAAGTAATGCTAGGG 3038 ACTTAT TGAG  4196  4218 CCCTAGCATTACTTATA 1270 ATATCATATAAGTAAT 3039 TGATAT GCTA  4197  4219 CCTAGCATTACTTATAT 1271 CATATCATATAAGTAA 3040 GATATG TGCT  4223  4245 CCATACCCATTACAATC 1272 GCTGGAGATTGTAATG 3041 TCCAGC GGTA  4228  4250 CCCATTACAATCTCCAG 1273 GGAATGCTGGAGATTG 3042 CATTCC TAAT  4229  4251 CCATTACAATCTCCAGC 1274 GGGAATGCTGGAGATT 3043 ATTCCC GTAA  4241  4263 CCAGCATTCCCCCTCAA 1275 TTAGGTTTGAGGGGGA 3044 ACCTAA ATGC  4249  4271 CCCCCTCAAACCTAAGA 1276 CATATTTCTTAGGTTT 3045 AATATG GAGG  4250  4272 CCCCTCAAACCTAAGAA 1277 ACATATTTCTTAGGTT 3046 ATATGT TGAG  4251  4273 CCCTCAAACCTAAGAAA 1278 GACATATTTCTTAGGT 3047 TATGTC TTGA  4252  4274 CCTCAAACCTAAGAAAT 1279 AGACATATTTCTTAGG 3048 ATGTCT TTTG  4259  4281 CCTAAGAAATATGTCTG 1280 TTTTATCAGACATATT 3049 ATAAAA TCTT  4318  4340 CCCCCTTATTTCTAGGA 1281 TCATAGTCCTAGAAAT 3050 CTATGA AAGG  4319  4341 CCCCTTATTTCTAGGAC 1282 CTCATAGTCCTAGAAA 3051 TATGAG TAAG  4320  4342 CCCTTATTTCTAGGACT 1283 TCTCATAGTCCTAGAA 3052 ATGAGA ATAA  4321  4343 CCTTATTTCTAGGACTA 1284 TTCTCATAGTCCTAGA 3053 TGAGAA AATA  4349  4371 CCCATCCCTGAGAATCC 1285 AATTTTGGATTCTCAG 3054 AAAATT GGAT  4350  4372 CCATCCCTGAGAATCCA 1286 GAATTTTGGATTCTCA 3055 AAATTC GGGA  4354  4376 CCCTGAGAATCCAAAAT 1287 CGGAGAATTTTGGATT 3056 TCTCCG CTCA  4355  4377 CCTGAGAATCCAAAATT 1288 ACGGAGAATTTTGGAT 3057 CTCCGT TCTC  4364  4386 CCAAAATTCTCCGTGCC 1289 ATAGGTGGCACGGAG 3058 ACCTAT AATTT  4374  4396 CCGTGCCACCTATCACA 1290 ATGGGGTGTGATAGGT 3059 CCCCAT GGCA  4379  4401 CCACCTATCACACCCCA 1291 TTAGGATGGGGTGTGA 3060 TCCTAA TAGG  4382  4404 CCTATCACACCCCATCC 1292 ACTTTAGGATGGGGTG 3061 TAAAGT TGAT  4391  4413 CCCCATCCTAAAGTAAG 1293 GCTGACCTTACTTTAG 3062 GTCAGC GATG  4392  4414 CCCATCCTAAAGTAAGG 1294 AGCTGACCTTACTTTA 3063 TCAGCT GGAT  4393  4415 CCATCCTAAAGTAAGGT 1295 TAGCTGACCTTACTTT 3064 CAGCTA AGGA  4397  4419 CCTAAAGTAAGGTCAGC 1296 TATTTAGCTGACCTTA 3065 TAAATA CTTT  4430  4452 CCCATACCCCGAAAATG 1297 AACCAACATTTTCGGG 3066 TTGGTT GTAT  4431  4453 CCATACCCCGAAAATGT 1298 TAACCAACATTTTCGG 3067 TGGTTA GGTA  4436  4458 CCCCGAAAATGTTGGTT 1299 GGGTATAACCAACATT 3068 ATACCC TTCG  4437  4459 CCCGAAAATGTTGGTTA 1300 AGGGTATAACCAACAT 3069 TACCCT TTTC  4438  4460 CCGAAAATGTTGGTTAT 1301 AAGGGTATAACCAAC 3070 ACCCTT ATTTT  4456  4478 CCCTTCCCGTACTAATT 1302 GGGATTAATTAGTACG 3071 AATCCC GGAA  4457  4479 CCTTCCCGTACTAATTA 1303 GGGGATTAATTAGTAC 3072 ATCCCC GGGA  4461  4483 CCCGTACTAATTAATCC 1304 GCCAGGGGATTAATTA 3073 CCTGGC GTAC  4462  4484 CCGTACTAATTAATCCC 1305 GGCCAGGGGATTAATT 3074 CTGGCC AGTA  4476  4498 CCCCTGGCCCAACCCGT 1306 TAGATGACGGGTTGGG 3075 CATCTA CCAG  4477  4499 CCCTGGCCCAACCCGTC 1307 GTAGATGACGGGTTGG 3076 ATCTAC GCCA  4478  4500 CCTGGCCCAACCCGTCA 1308 AGTAGATGACGGGTTG 3077 TCTACT GGCC  4483  4505 CCCAACCCGTCATCTAC 1309 GGTAGAGTAGATGAC 3078 TCTACC GGGTT  4484  4506 CCAACCCGTCATCTACT 1310 TGGTAGAGTAGATGAC 3079 CTACCA GGGT  4488  4510 CCCGTCATCTACTCTAC 1311 AAGATGGTAGAGTAG 3080 CATCTT ATGAC  4489  4511 CCGTCATCTACTCTACC 1312 AAAGATGGTAGAGTA 3081 ATCTTT GATGA  4504  4526 CCATCTTTGCAGGCACA 1313 GATGAGTGTGCCTGCA 3082 CTCATC AAGA  4555  4577 CCTGAGTAGGCCTAGAA 1314 GTTTATTTCTAGGCCT 3083 ATAAAC ACTC  4565  4587 CCTAGAAATAAACATGC 1315 AAGCTAGCATGTTTAT 3084 TAGCTT TTCT  4593  4615 CCAGTTCTAACCAAAAA 1316 TTTATTTTTTTGGTTAG 3085 AATAAA AAC  4603  4625 CCAAAAAAATAAACCCT 1317 GGAACGAGGGTTTATT 3086 CGTTCC TTTT  4616  4638 CCCTCGTTCCACAGAAG 1318 TGGCAGCTTCTGTGGA 3087 CTGCCA ACGA  4617  4639 CCTCGTTCCACAGAAGC 1319 ATGGCAGCTTCTGTGG 3088 TGCCAT AACG  4624  4646 CCACAGAAGCTGCCATC 1320 ATACTTGATGGCAGCT 3089 AAGTAT TCTG  4636  4658 CCATCAAGTATTTCCTC 1321 TTGCGTGAGGAAATAC 3090 ACGCAA TTGA  4649  4671 CCTCACGCAAGCAACCG 1322 TGGATGCGGTTGCTTG 3091 CATCCA CGTG  4663  4685 CCGCATCCATAATCCTT 1323 TATTAGAAGGATTATG 3092 CTAATA GATG  4669  4691 CCATAATCCTTCTAATA 1324 GATAGCTATTAGAAGG 3093 GCTATC ATTA  4676  4698 CCTTCTAATAGCTATCC 1325 TGAAGAGGATAGCTAT 3094 TCTTCA TAGA  4691  4713 CCTCTTCAACAATATAC 1326 CGGAGAGTATATTGTT 3095 TCTCCG GAAG  4711  4733 CCGGACAATGAACCATA 1327 ATTGGTTATGGTTCAT 3096 ACCAAT TGTC  4723  4745 CCATAACCAATACTACC 1328 TTGATTGGTAGTATTG 3097 AATCAA GTTA  4729  4751 CCAATACTACCAATCAA 1329 TGAGTATTGATTGGTA 3098 TACTCA GTAT  4738  4760 CCAATCAATACTCATCA 1330 TATTAATGATGAGTAT 3099 TTAATA TGAT  4795  4817 CCCCCTTTCACTTCTGA 1331 TGGGACTCAGAAGTGA 3100 GTCCCA AAGG  4796  4818 CCCCTTTCACTTCTGAG 1332 CTGGGACTCAGAAGTG 3101 TCCCAG AAAG  4797  4819 CCCTTTCACTTCTGAGT 1333 TCTGGGACTCAGAAGT 3102 CCCAGA GAAA  4798  4820 CCTTTCACTTCTGAGTC 1334 CTCTGGGACTCAGAAG 3103 CCAGAG TGAA  4814  4836 CCCAGAGGTTACCCAAG 1335 GGGTGCCTTGGGTAAC 3104 GCACCC CTCT  4815  4837 CCAGAGGTTACCCAAGG 1336 GGGGTGCCTTGGGTAA 3105 CACCCC CCTC  4825  4847 CCCAAGGCACCCCTCTG 1337 GGATGTCAGAGGGGT 3106 ACATCC GCCTT  4826  4848 CCAAGGCACCCCTCTGA 1338 CGGATGTCAGAGGGGT 3107 CATCCG GCCT  4834  4856 CCCCTCTGACATCCGGC 1339 AAGCAGGCCGGATGTC 3108 CTGCTT AGAG  4835  4857 CCCTCTGACATCCGGCC 1340 GAAGCAGGCCGGATG 3109 TGCTTC TCAGA  4836  4858 CCTCTGACATCCGGCCT 1341 AGAAGCAGGCCGGAT 3110 GCTTCT GTCAG  4846  4868 CCGGCCTGCTTCTTCTC 1342 TCATGTGAGAAGAAGC 3111 ACATGA AGGC  4850  4872 CCTGCTTCTTCTCACAT 1343 TTTGTCATGTGAGAAG 3112 GACAAA AAGC  4879  4901 CCCCCATCTCAATCATA 1344 TTGGTATATGATTGAG 3113 TACCAA ATGG  4880  4902 CCCCATCTCAATCATAT 1345 TTTGGTATATGATTGA 3114 ACCAAA GATG  4881  4903 CCCATCTCAATCATATA 1346 ATTTGGTATATGATTG 3115 CCAAAT AGAT  4882  4904 CCATCTCAATCATATAC 1347 GATTTGGTATATGATT 3116 CAAATC GAGA  4898  4920 CCAAATCTCTCCCTCAC 1348 CGTTTAGTGAGGGAGA 3117 TAAACG GATT  4908  4930 CCCTCACTAAACGTAAG 1349 AGAAGGCTTACGTTTA 3118 CCTTCT GTGA  4909  4931 CCTCACTAAACGTAAGC 1350 GAGAAGGCTTACGTTT 3119 CTTCTC AGTG  4925  4947 CCTTCTCCTCACTCTCTC 1351 AGATTGAGAGAGTGA 3120 AATCT GGAGA  4931  4953 CCTCACTCTCTCAATCTT 1352 TGGATAAGATTGAGAG 3121 ATCCA AGTG  4951  4973 CCATCATAGCAGGCAGT 1353 ACCTCAACTGCCTGCT 3122 TGAGGT ATGA  4982  5004 CCAAACCCAGCTACGCA 1354 AGATTTTGCGTAGCTG 3123 AAATCT GGTT  4987  5009 CCCAGCTACGCAAAATC 1355 TGCTAAGATTTTGCGT 3124 TTAGCA AGCT  4988  5010 CCAGCTACGCAAAATCT 1356 ATGCTAAGATTTTGCG 3125 TAGCAT TAGC  5014  5036 CCTCAATTACCCACATA 1357 TCATCCTATGTGGGTA 3126 GGATGA ATTG  5023  5045 CCCACATAGGATGAATA 1358 TGCTATTATTCATCCT 3127 ATAGCA ATGT  5024  5046 CCACATAGGATGAATAA 1359 CTGCTATTATTCATCCT 3128 TAGCAG ATG  5052  5074 CCGTACAACCCTAACAT 1360 ATGGTTATGTTAGGGT 3129 AACCAT TGTA  5060  5082 CCCTAACATAACCATTC 1361 AATTAAGAATGGTTAT 3130 TTAATT GTTA  5061  5083 CCTAACATAACCATTCT 1362 AAATTAAGAATGGTTA 3131 TAATTT TGTT  5071  5093 CCATTCTTAATTTAACT 1363 ATAAATAGTTAAATTA 3132 ATTTAT AGAA  5099  5121 CCTAACTACTACCGCAT 1364 GTAGGAATGCGGTAGT 3133 TCCTAC AGTT  5110  5132 CCGCATTCCTACTACTC 1365 TAAGTTGAGTAGTAGG 3134 AACTTA AATG  5117  5139 CCTACTACTCAACTTAA 1366 TGGAGTTTAAGTTGAG 3135 ACTCCA TAGT  5137  5159 CCAGCACCACGACCCTA 1367 TAGTAGTAGGGTCGTG 3136 CTACTA GTGC  5143  5165 CCACGACCCTACTACTA 1368 GCGAGATAGTAGTAG 3137 TCTCGC GGTCG  5149  5171 CCCTACTACTATCTCGC 1369 TCAGGTGCGAGATAGT 3138 ACCTGA AGTA  5150  5172 CCTACTACTATCTCGCA 1370 TTCAGGTGCGAGATAG 3139 CCTGAA TAGT  5167  5189 CCTGAAACAAGCTAACA 1371 TAGTCATGTTAGCTTG 3140 TGACTA TTTC  5193  5215 CCCTTAATTCCATCCAC 1372 AGGAGGGTGGATGGA 3141 CCTCCT ATTAA  5194  5216 CCTTAATTCCATCCACC 1373 GAGGAGGGTGGATGG 3142 CTCCTC AATTA  5202  5224 CCATCCACCCTCCTCTC 1374 CCTAGGGAGAGGAGG 3143 CCTAGG GTGGA  5206  5228 CCACCCTCCTCTCCCTA 1375 GCCTCCTAGGGAGAGG 3144 GGAGGC AGGG  5209  5231 CCCTCCTCTCCCTAGGA 1376 CAGGCCTCCTAGGGAG 3145 GGCCTG AGGA  5210  5232 CCTCCTCTCCCTAGGAG 1377 GCAGGCCTCCTAGGGA 3146 GCCTGC GAGG  5213  5235 CCTCTCCCTAGGAGGCC 1378 GGGGCAGGCCTCCTAG 3147 TGCCCC GGAG  5218  5240 CCCTAGGAGGCCTGCCC 1379 TAGCGGGGGCAGGCCT 3148 CCGCTA CCTA  5219  5241 CCTAGGAGGCCTGCCCC 1380 TTAGCGGGGGCAGGCC 3149 CGCTAA TCCT  5228  5250 CCTGCCCCCGCTAACCG 1381 AAAAGCCGGTTAGCG 3150 GCTTTT GGGGC  5232  5254 CCCCCGCTAACCGGCTT 1382 GGCAAAAAGCCGGTT 3151 TTTGCC AGCGG  5233  5255 CCCCGCTAACCGGCTTT 1383 GGGCAAAAAGCCGGT 3152 TTGCCC TAGCG  5234  5256 CCCGCTAACCGGCTTTT 1384 TGGGCAAAAAGCCGG 3153 TGCCCA TTAGC  5235  5257 CCGCTAACCGGCTTTTT 1385 TTGGGCAAAAAGCCG 3154 GCCCAA GTTAG  5242  5264 CCGGCTTTTTGCCCAAA 1386 GGCCCATTTGGGCAAA 3155 TGGGCC AAGC  5253  5275 CCCAAATGGGCCATTAT 1387 TCTTCGATAATGGCCC 3156 CGAAGA ATTT  5254  5276 CCAAATGGGCCATTATC 1388 TTCTTCGATAATGGCC 3157 GAAGAA CATT  5263  5285 CCATTATCGAAGAATTC 1389 TTTTGTGAATTCTTCG 3158 ACAAAA ATAA  5294  5316 CCTCATCATCCCCACCA 1390 CTATGATGGTGGGGAT 3159 TCATAG GATG  5303  5325 CCCCACCATCATAGCCA 1391 TGATGGTGGCTATGAT 3160 CCATCA GGTG  5304  5326 CCCACCATCATAGCCAC 1392 GTGATGGTGGCTATGA 3161 CATCAC TGGT  5305  5327 CCACCATCATAGCCACC 1393 GGTGATGGTGGCTATG 3162 ATCACC ATGG  5308  5330 CCATCATAGCCACCATC 1394 GAGGGTGATGGTGGCT 3163 ACCCTC ATGA  5317  5339 CCACCATCACCCTCCTT 1395 GAGGTTAAGGAGGGT 3164 AACCTC GATGG  5320  5342 CCATCACCCTCCTTAAC 1396 GTAGAGGTTAAGGAG 3165 CTCTAC GGTGA  5326  5348 CCCTCCTTAACCTCTAC 1397 GTAGAAGTAGAGGTTA 3166 TTCTAC AGGA  5327  5349 CCTCCTTAACCTCTACTT 1398 GGTAGAAGTAGAGGTT 3167 CTACC AAGG  5330  5352 CCTTAACCTCTACTTCT 1399 GTAGGTAGAAGTAGA 3168 ACCTAC GGTTA  5336  5358 CCTCTACTTCTACCTAC 1400 TTAGGCGTAGGTAGAA 3169 GCCTAA GTAG  5348  5370 CCTACGCCTAATCTACT 1401 AGGTGGAGTAGATTAG 3170 CCACCT GCGT  5354  5376 CCTAATCTACTCCACCT 1402 TGATTGAGGTGGAGTA 3171 CAATCA GATT  5365  5387 CCACCTCAATCACACTA 1403 GGGGAGTAGTGTGATT 3172 CTCCCC GAGG  5368  5390 CCTCAATCACACTACTC 1404 TATGGGGAGTAGTGTG 3173 CCCATA ATTG  5384  5406 CCCCATATCTAACAACG 1405 TTTTTACGTTGTTAGAT 3174 TAAAAA ATG  5385  5407 CCCATATCTAACAACGT 1406 ATTTTTACGTTGTTAG 3175 AAAAAT ATAT  5386  5408 CCATATCTAACAACGTA 1407 TATTTTTACGTTGTTAG 3176 AAAATA ATA  5433  5455 CCCACCCCATTCCTCCC 1408 AGTGTGGGGAGGAAT 3177 CACACT GGGGT  5434  5456 CCACCCCATTCCTCCCC 1409 GAGTGTGGGGAGGAA 3178 ACACTC TGGGG  5437  5459 CCCCATTCCTCCCCACA 1410 GATGAGTGTGGGGAG 3179 CTCATC GAATG  5438  5460 CCCATTCCTCCCCACAC 1411 CGATGAGTGTGGGGA 3180 TCATCG GGAAT  5439  5461 CCATTCCTCCCCACACT 1412 GCGATGAGTGTGGGG 3181 CATCGC AGGAA  5444  5466 CCTCCCCACACTCATCG 1413 TAAGGGCGATGAGTGT 3182 CCCTTA GGGG  5447  5469 CCCCACACTCATCGCCC 1414 TGGTAAGGGCGATGA 3183 TTACCA GTGTG  5448  5470 CCCACACTCATCGCCCT 1415 GTGGTAAGGGCGATG 3184 TACCAC AGTGT  5449  5471 CCACACTCATCGCCCTT 1416 CGTGGTAAGGGCGATG 3185 ACCACG AGTG  5461  5483 CCCTTACCACGCTACTC 1417 AGGTAGGAGTAGCGT 3186 CTACCT GGTAA  5462  5484 CCTTACCACGCTACTCC 1418 TAGGTAGGAGTAGCGT 3187 TACCTA GGTA  5467  5489 CCACGCTACTCCTACCT 1419 GGAGATAGGTAGGAG 3188 ATCTCC TAGCG  5477  5499 CCTACCTATCTCCCCTTT 1420 GTATAAAAGGGGAGA 3189 TATAC TAGGT  5481  5503 CCTATCTCCCCTTTTATA 1421 ATTAGTATAAAAGGGG 3190 CTAAT AGAT  5488  5510 CCCCTTTTATACTAATA 1422 TAAGATTATTAGTATA 3191 ATCTTA AAAG  5489  5511 CCCTTTTATACTAATAA 1423 ATAAGATTATTAGTAT 3192 TCTTAT AAAA  5490  5512 CCTTTTATACTAATAAT 1424 TATAAGATTATTAGTA 3193 CTTATA TAAA  5534  5556 CCAAGAGCCTTCAAAGC 1425 CTGAGGGCTTTGAAGG 3194 CCTCAG CTCT  5541  5563 CCTTCAAAGCCCTCAGT 1426 CAACTTACTGAGGGCT 3195 AAGTTG TTGA  5550  5572 CCCTCAGTAAGTTGCAA 1427 TAAGTATTGCAACTTA 3196 TACTTA CTGA  5551  5573 CCTCAGTAAGTTGCAAT 1428 TTAAGTATTGCAACTT 3197 ACTTAA ACTG  5601  5623 CCCCACTCTGCATCAAC 1429 CGTTCAGTTGATGCAG 3198 TGAACG AGTG  5602  5624 CCCACTCTGCATCAACT 1430 GCGTTCAGTTGATGCA 3199 GAACGC GAGT  5603  5625 CCACTCTGCATCAACTG 1431 TGCGTTCAGTTGATGC 3200 AACGCA AGAG  5632  5654 CCACTTTAATTAAGCTA 1432 AGGGCTTAGCTTAATT 3201 AGCCCT AAAG  5651  5673 CCCTTACTAGACCAATG 1433 AAGTCCCATTGGTCTA 3202 GGACTT GTAA  5652  5674 CCTTACTAGACCAATGG 1434 TAAGTCCCATTGGTCT 3203 GACTTA AGTA  5662  5684 CCAATGGGACTTAAACC 1435 TTTGTGGGTTTAAGTC 3204 CACAAA CCAT  5677  5699 CCCACAAACACTTAGTT 1436 GCTGTTAACTAAGTGT 3205 AACAGC TTGT  5678  5700 CCACAAACACTTAGTTA 1437 AGCTGTTAACTAAGTG 3206 ACAGCT TTTG  5706  5728 CCCTAATCAACTGGCTT 1438 AGATTGAAGCCAGTTG 3207 CAATCT ATTA  5707  5729 CCTAATCAACTGGCTTC 1439 TAGATTGAAGCCAGTT 3208 AATCTA GATT  5735  5757 CCCGCCGCCGGGAAAA 1440 CCGCCTTTTTTCCCGG 3209 AAGGCGG CGGC  5736  5758 CCGCCGCCGGGAAAAA 1441 CCCGCCTTTTTTCCCG 3210 AGGCGGG GCGG  5739  5761 CCGCCGGGAAAAAAGG 1442 TCTCCCGCCTTTTTTCC 3211 CGGGAGA CGG  5742  5764 CCGGGAAAAAAGGCGG 1443 GCTTCTCCCGCCTTTTT 3212 GAGAAGC TCC  5764  5786 CCCCGGCAGGTTTGAAG 1444 AAGCAGCTTCAAACCT 3213 CTGCTT GCCG  5765  5787 CCCGGCAGGTTTGAAGC 1445 GAAGCAGCTTCAAACC 3214 TGCTTC TGCC  5766  5788 CCGGCAGGTTTGAAGCT 1446 AGAAGCAGCTTCAAAC 3215 GCTTCT CTGC  5817  5839 CCTCGGAGCTGGTAAAA 1447 GCCTCTTTTTACCAGC 3216 AGAGGC TCCG  5839  5861 CCTAACCCCTGTCTTTA 1448 TAAATCTAAAGACAGG 3217 GATTTA GGTT  5844  5866 CCCCTGTCTTTAGATTT 1449 GACTGTAAATCTAAAG 3218 ACAGTC ACAG  5845  5867 CCCTGTCTTTAGATTTA 1450 GGACTGTAAATCTAAA 3219 CAGTCC GACA  5846  5868 CCTGTCTTTAGATTTAC 1451 TGGACTGTAAATCTAA 3220 AGTCCA AGAC  5866  5888 CCAATGCTTCACTCAGC 1452 AAAATGGCTGAGTGA 3221 CATTTT AGCAT  5882  5904 CCATTTTACCTCACCCC 1453 TCAGTGGGGGTGAGGT 3222 CACTGA AAAA  5890  5912 CCTCACCCCCACTGATG 1454 GGCGAACATCAGTGG 3223 TTCGCC GGGTG  5895  5917 CCCCCACTGATGTTCGC 1455 CGGTCGGCGAACATCA 3224 CGACCG GTGG  5896  5918 CCCCACTGATGTTCGCC 1456 ACGGTCGGCGAACATC 3225 GACCGT AGTG  5897  5919 CCCACTGATGTTCGCCG 1457 AACGGTCGGCGAACAT 3226 ACCGTT CAGT  5898  5920 CCACTGATGTTCGCCGA 1458 CAACGGTCGGCGAAC 3227 CCGTTG ATCAG  5911  5933 CCGACCGTTGACTATTC 1459 TGTAGAGAATAGTCAA 3228 TCTACA CGGT  5915  5937 CCGTTGACTATTCTCTA 1460 GGTTTGTAGAGAATAG 3229 CAAACC TCAA  5936  5958 CCACAAAGACATTGGA 1461 ATAGTGTTCCAATGTC 3230 ACACTAT TTTG  5960  5982 CCTATTATTCGGCGCAT 1462 CAGCTCATGCGCCGAA 3231 GAGCTG TAAT  5987  6009 CCTAGGCACAGCTCTAA 1463 GGAGGCTTAGAGCTGT 3232 GCCTCC GCCT  6005  6027 CCTCCTTATTCGAGCCG 1464 CCAGCTCGGCTCGAAT 3233 AGCTGG AAGG  6008  6030 CCTTATTCGAGCCGAGC 1465 GGCCCAGCTCGGCTCG 3234 TGGGCC AATA  6019  6041 CCGAGCTGGGCCAGCCA 1466 GTTGCCTGGCTGGCCC 3235 GGCAAC AGCT  6029  6051 CCAGCCAGGCAACCTTC 1467 TACCTAGAAGGTTGCC 3236 TAGGTA TGGC  6033  6055 CCAGGCAACCTTCTAGG 1468 TCGTTACCTAGAAGGT 3237 TAACGA TGCC  6041  6063 CCTTCTAGGTAACGACC 1469 AGATGTGGTCGTTACC 3238 ACATCT TAGA  6056  6078 CCACATCTACAACGTTA 1470 TGACGATAACGTTGTA 3239 TCGTCA GATG  6082  6104 CCCATGCATTTGTAATA 1471 GAAGATTATTACAAAT 3240 ATCTTC GCAT  6083  6105 CCATGCATTTGTAATAA 1472 AGAAGATTATTACAAA 3241 TCTTCT TGCA  6117  6139 CCCATCATAATCGGAGG 1473 CCAAAGCCTCCGATTA 3242 CTTTGG TGAT  6118  6140 CCATCATAATCGGAGGC 1474 GCCAAAGCCTCCGATT 3243 TTTGGC ATGA  6153  6175 CCCCTAATAATCGGTGC 1475 TCGGGGGCACCGATTA 3244 CCCCGA TTAG  6154  6176 CCCTAATAATCGGTGCC 1476 ATCGGGGGCACCGATT 3245 CCCGAT ATTA  6155  6177 CCTAATAATCGGTGCCC 1477 TATCGGGGGCACCGAT 3246 CCGATA TATT  6169  6191 CCCCCGATATGGCGTTT 1478 GCGGGGAAACGCCAT 3247 CCCCGC ATCGG  6170  6192 CCCCGATATGGCGTTTC 1479 TGCGGGGAAACGCCAT 3248 CCCGCA ATCG  6171  6193 CCCGATATGGCGTTTCC 1480 ATGCGGGGAAACGCC 3249 CCGCAT ATATC  6172  6194 CCGATATGGCGTTTCCC 1481 TATGCGGGGAAACGCC 3250 CGCATA ATAT  6186  6208 CCCCGCATAAACAACAT 1482 AAGCTTATGTTGTTTA 3251 AAGCTT TGCG  6187  6209 CCCGCATAAACAACATA 1483 GAAGCTTATGTTGTTT 3252 AGCTTC ATGC  6188  6210 CCGCATAAACAACATAA 1484 AGAAGCTTATGTTGTT 3253 GCTTCT TATG  6219  6241 CCTCCCTCTCTCCTACTC 1485 AGCAGGAGTAGGAGA 3254 CTGCT GAGGG  6222  6244 CCCTCTCTCCTACTCCTG 1486 GCGAGCAGGAGTAGG 3255 CTCGC AGAGA  6223  6245 CCTCTCTCCTACTCCTGC 1487 TGCGAGCAGGAGTAG 3256 TCGCA GAGAG  6230  6252 CCTACTCCTGCTCGCAT 1488 TAGCAGATGCGAGCA 3257 CTGCTA GGAGT  6236  6258 CCTGCTCGCATCTGCTA 1489 CCACTATAGCAGATGC 3258 TAGTGG GAGC  6262  6284 CCGGAGCAGGAACAGG 1490 TGTTCAACCTGTTCCT 3259 TTGAACA GCTC  6290  6312 CCCTCCCTTAGCAGGGA 1491 AGTAGTTCCCTGCTAA 3260 ACTACT GGGA  6291  6313 CCTCCCTTAGCAGGGAA 1492 GAGTAGTTCCCTGCTA 3261 CTACTC AGGG  6294  6316 CCCTTAGCAGGGAACTA 1493 TGGGAGTAGTTCCCTG 3262 CTCCCA CTAA  6295  6317 CCTTAGCAGGGAACTAC 1494 GTGGGAGTAGTTCCCT 3263 TCCCAC GCTA  6313  6335 CCCACCCTGGAGCCTCC 1495 GTCTACGGAGGCTCCA 3264 GTAGAC GGGT  6314  6336 CCACCCTGGAGCCTCCG 1496 GGTCTACGGAGGCTCC 3265 TAGACC AGGG  6317  6339 CCCTGGAGCCTCCGTAG 1497 TTAGGTCTACGGAGGC 3266 ACCTAA TCCA  6318  6340 CCTGGAGCCTCCGTAGA 1498 GTTAGGTCTACGGAGG 3267 CCTAAC CTCC  6325  6347 CCTCCGTAGACCTAACC 1499 GAAGATGGTTAGGTCT 3268 ATCTTC ACGG  6328  6350 CCGTAGACCTAACCATC 1500 GGAGAAGATGGTTAG 3269 TTCTCC GTCTA  6335  6357 CCTAACCATCTTCTCCTT 1501 GGTGTAAGGAGAAGA 3270 ACACC TGGTT  6340  6362 CCATCTTCTCCTTACAC 1502 TGCTAGGTGTAAGGAG 3271 CTAGCA AAGA  6349  6371 CCTTACACCTAGCAGGT 1503 GGAGACACCTGCTAGG 3272 GTCTCC TGTA  6356  6378 CCTAGCAGGTGTCTCCT 1504 AGATAGAGGAGACAC 3273 CTATCT CTGCT  6370  6392 CCTCTATCTTAGGGGCC 1505 ATTGATGGCCCCTAAG 3274 ATCAAT ATAG  6385  6407 CCATCAATTTCATCACA 1506 AATTGTTGTGATGAAA 3275 ACAATT TTGA  6420  6442 CCCCCTGCCATAACCCA 1507 TGGTATTGGGTTATGG 3276 ATACCA CAGG  6421  6443 CCCCTGCCATAACCCAA 1508 TTGGTATTGGGTTATG 3277 TACCAA GCAG  6422  6444 CCCTGCCATAACCCAAT 1509 TTTGGTATTGGGTTAT 3278 ACCAAA GGCA  6423  6445 CCTGCCATAACCCAATA 1510 GTTTGGTATTGGGTTA 3279 CCAAAC TGGC  6427  6449 CCATAACCCAATACCAA 1511 GGGCGTTTGGTATTGG 3280 ACGCCC GTTA  6433  6455 CCCAATACCAAACGCCC 1512 GAAGAGGGGCGTTTG 3281 CTCTTC GTATT  6434  6456 CCAATACCAAACGCCCC 1513 CGAAGAGGGGCGTTTG 3282 TCTTCG GTAT  6440  6462 CCAAACGCCCCTCTTCG 1514 ATCAGACGAAGAGGG 3283 TCTGAT GCGTT  6447  6469 CCCCTCTTCGTCTGATC 1515 AGGACGGATCAGACG 3284 CGTCCT AAGAG  6448  6470 CCCTCTTCGTCTGATCC 1516 TAGGACGGATCAGAC 3285 GTCCTA GAAGA  6449  6471 CCTCTTCGTCTGATCCG 1517 TTAGGACGGATCAGAC 3286 TCCTAA GAAG  6463  6485 CCGTCCTAATCACAGCA 1518 TAGGACTGCTGTGATT 3287 GTCCTA AGGA  6467  6489 CCTAATCACAGCAGTCC 1519 GAAGTAGGACTGCTGT 3288 TACTTC GATT  6482  6504 CCTACTTCTCCTATCTCT 1520 CTGGGAGAGATAGGA 3289 CCCAG GAAGT  6491  6513 CCTATCTCTCCCAGTCC 1521 CAGCTAGGACTGGGA 3290 TAGCTG GAGAT  6500  6522 CCCAGTCCTAGCTGCTG 1522 TGATGCCAGCAGCTAG 3291 GCATCA GACT  6501  6523 CCAGTCCTAGCTGCTGG 1523 GTGATGCCAGCAGCTA 3292 CATCAC GGAC  6506  6528 CCTAGCTGCTGGCATCA 1524 GTATAGTGATGCCAGC 3293 CTATAC AGCT  6539  6561 CCGCAACCTCAACACCA 1525 AGAAGGTGGTGTTGAG 3294 CCTTCT GTTG  6545  6567 CCTCAACACCACCTTCT 1526 GGTCGAAGAAGGTGG 3295 TCGACC TGTTG  6553  6575 CCACCTTCTTCGACCCC 1527 TCCGGCGGGGTCGAAG 3296 GCCGGA AAGG  6556  6578 CCTTCTTCGACCCCGCC 1528 TCCTCCGGCGGGGTCG 3297 GGAGGA AAGA  6566  6588 CCCCGCCGGAGGAGGA 1529 TGGGGTCTCCTCCTCC 3298 GACCCCA GGCG  6567  6589 CCCGCCGGAGGAGGAG 1530 ATGGGGTCTCCTCCTC 3299 ACCCCAT CGGC  6568  6590 CCGCCGGAGGAGGAGA 1531 AATGGGGTCTCCTCCT 3300 CCCCATT CCGG  6571  6593 CCGGAGGAGGAGACCC 1532 TAGAATGGGGTCTCCT 3301 CATTCTA CCTC  6584  6606 CCCCATTCTATACCAAC 1533 ATAGGTGTTGGTATAG 3302 ACCTAT AATG  6585  6607 CCCATTCTATACCAACA 1534 AATAGGTGTTGGTATA 3303 CCTATT GAAT  6586  6608 CCATTCTATACCAACAC 1535 GAATAGGTGTTGGTAT 3304 CTATTC AGAA  6596  6618 CCAACACCTATTCTGAT 1536 CGAAAAATCAGAATA 3305 TTTTCG GGTGT  6602  6624 CCTATTCTGATTTTTCGG 1537 GGTGACCGAAAAATC 3306 TCACC AGAAT  6623  6645 CCCTGAAGTTTATATTC 1538 GGATAAGAATATAAA 3307 TTATCC CTTCA  6624  6646 CCTGAAGTTTATATTCT 1539 AGGATAAGAATATAA 3308 TATCCT ACTTC  6644  6666 CCTACCAGGCTTCGGAA 1540 AGATTATTCCGAAGCC 3309 TAATCT TGGT  6648  6670 CCAGGCTTCGGAATAAT 1541 TGGGAGATTATTCCGA 3310 CTCCCA AGCC  6667  6689 CCCATATTGTAACTTAC 1542 GGAGTAGTAAGTTACA 3311 TACTCC ATAT  6668  6690 CCATATTGTAACTTACT 1543 CGGAGTAGTAAGTTAC 3312 ACTCCG AATA  6688  6710 CCGGAAAAAAAGAACC 1544 TCCAAATGGTTCTTTTT 3313 ATTTGGA TTC  6702  6724 CCATTTGGATACATAGG 1545 ACCATACCTATGTATC 3314 TATGGT CAAA  6749  6771 CCTAGGGTTTATCGTGT 1546 GTGCTCACACGATAAA 3315 GAGCAC CCCT  6773  6795 CCATATATTTACAGTAG 1547 CTATTCCTACTGTAAA 3316 GAATAG TATA  6820  6842 CCTCCGCTACCATAATC 1548 AGCGATGATTATGGTA 3317 ATCGCT GCGG  6823  6845 CCGCTACCATAATCATC 1549 GATAGCGATGATTATG 3318 GCTATC GTAG  6829  6851 CCATAATCATCGCTATC 1550 GGTGGGGATAGCGAT 3319 CCCACC GATTA  6845  6867 CCCCACCGGCGTCAAAG 1551 TAAATACTTTGACGCC 3320 TATTTA GGTG  6846  6868 CCCACCGGCGTCAAAGT 1552 CTAAATACTTTGACGC 3321 ATTTAG CGGT  6847  6869 CCACCGGCGTCAAAGTA 1553 GCTAAATACTTTGACG 3322 TTTAGC CCGG  6850  6872 CCGGCGTCAAAGTATTT 1554 TCAGCTAAATACTTTG 3323 AGCTGA ACGC  6877  6899 CCACACTCCACGGAAGC 1555 CATATTGCTTCCGTGG 3324 AATATG AGTG  6884  6906 CCACGGAAGCAATATG 1556 ATCATTTCATATTGCTT 3325 AAATGAT CCG  6925  6947 CCCTAGGATTCATCTTT 1557 GAAAAGAAAGATGAA 3326 CTTTTC TCCTA  6926  6948 CCTAGGATTCATCTTTC 1558 TGAAAAGAAAGATGA 3327 TTTTCA ATCCT  6949  6971 CCGTAGGTGGCCTGACT 1559 AATGCCAGTCAGGCCA 3328 GGCATT CCTA  6959  6981 CCTGACTGGCATTGTAT 1560 TTGCTAATACAATGCC 3329 TAGCAA AGTC  7027  7049 CCCACTTCCACTATGTC 1561 TGATAGGACATAGTGG 3330 CTATCA AAGT  7028  7050 CCACTTCCACTATGTCC 1562 TTGATAGGACATAGTG 3331 TATCAA GAAG  7034  7056 CCACTATGTCCTATCAA 1563 CTCCTATTGATAGGAC 3332 TAGGAG ATAG  7043  7065 CCTATCAATAGGAGCTG 1564 CAAATACAGCTCCTAT 3333 TATTTG TGAT  7066  7088 CCATCATAGGAGGCTTC 1565 GTGAATGAAGCCTCCT 3334 ATTCAC ATGA  7095  7117 CCCCTATTCTCAGGCTA 1566 AGGGTGTAGCCTGAGA 3335 CACCCT ATAG  7096  7118 CCCTATTCTCAGGCTAC 1567 TAGGGTGTAGCCTGAG 3336 ACCCTA AATA  7097  7119 CCTATTCTCAGGCTACA 1568 CTAGGGTGTAGCCTGA 3337 CCCTAG GAAT  7114  7136 CCCTAGACCAAACCTAC 1569 TTTGGCGTAGGTTTGG 3338 GCCAAA TCTA  7115  7137 CCTAGACCAAACCTACG 1570 TTTTGGCGTAGGTTTG 3339 CCAAAA GTCT  7121  7143 CCAAACCTACGCCAAAA 1571 AATGGATTTTGGCGTA 3340 TCCATT GGTT  7126  7148 CCTACGCCAAAATCCAT 1572 AGTGAAATGGATTTTG 3341 TTCACT GCGT  7132  7154 CCAAAATCCATTTCACT 1573 TATGATAGTGAAATGG 3342 ATCATA ATTT  7139  7161 CCATTTCACTATCATAT 1574 CGATGAATATGATAGT 3343 TCATCG GAAA  7181  7203 CCCACAACACTTTCTCG 1575 ATAGGCCGAGAAAGT 3344 GCCTAT GTTGT  7182  7204 CCACAACACTTTCTCGG 1576 GATAGGCCGAGAAAG 3345 CCTATC TGTTG  7199  7221 CCTATCCGGAATGCCCC 1577 AACGTCGGGGCATTCC 3346 GACGTT GGAT  7204  7226 CCGGAATGCCCCGACGT 1578 CGAGTAACGTCGGGGC 3347 TACTCG ATTC  7212  7234 CCCCGACGTTACTCGGA 1579 GGGTAGTCCGAGTAAC 3348 CTACCC GTCG  7213  7235 CCCGACGTTACTCGGAC 1580 GGGGTAGTCCGAGTAA 3349 TACCCC CGTC  7214  7236 CCGACGTTACTCGGACT 1581 CGGGGTAGTCCGAGTA 3350 ACCCCG ACGT  7232  7254 CCCCGATGCATACACCA 1582 TTCATGTGGTGTATGC 3351 CATGAA ATCG  7233  7255 CCCGATGCATACACCAC 1583 TTTCATGTGGTGTATG 3352 ATGAAA CATC  7234  7256 CCGATGCATACACCACA 1584 GTTTCATGTGGTGTAT 3353 TGAAAC GCAT  7246  7268 CCACATGAAACATCCTA 1585 AGATGATAGGATGTTT 3354 TCATCT CATG  7259  7281 CCTATCATCTGTAGGCT 1586 TGAATGAGCCTACAGA 3355 CATTCA TGAT  7327  7349 CCTTCGCTTCGAAGCGA 1587 GACTTTTCGCTTCGAA 3356 AAAGTC GCGA  7349  7371 CCTAATAGTAGAAGAAC 1588 TGGAGGGTTCTTCTAC 3357 CCTCCA TATT  7365  7387 CCCTCCATAAACCTGGA 1589 AGTCACTCCAGGTTTA 3358 GTGACT TGGA  7366  7388 CCTCCATAAACCTGGAG 1590 TAGTCACTCCAGGTTT 3359 TGACTA ATGG  7369  7391 CCATAAACCTGGAGTGA 1591 ATATAGTCACTCCAGG 3360 CTATAT TTTA  7376  7398 CCTGGAGTGACTATATG 1592 GGCATCCATATAGTCA 3361 GATGCC CTCC  7397  7419 CCCCCCACCCTACCACA 1593 CGAATGTGTGGTAGGG 3362 CATTCG TGGG  7398  7420 CCCCCACCCTACCACAC 1594 TCGAATGTGTGGTAGG 3363 ATTCGA GTGG  7399  7421 CCCCACCCTACCACACA 1595 TTCGAATGTGTGGTAG 3364 TTCGAA GGTG  7400  7422 CCCACCCTACCACACAT 1596 CTTCGAATGTGTGGTA 3365 TCGAAG GGGT  7401  7423 CCACCCTACCACACATT 1597 TCTTCGAATGTGTGGT 3366 CGAAGA AGGG  7404  7426 CCCTACCACACATTCGA 1598 GGTTCTTCGAATGTGT 3367 AGAACC GGTA  7405  7427 CCTACCACACATTCGAA 1599 GGGTTCTTCGAATGTG 3368 GAACCC TGGT  7409  7431 CCACACATTCGAAGAAC 1600 ATACGGGTTCTTCGAA 3369 CCGTAT TGTG  7425  7447 CCCGTATACATAAAATC 1601 TGTCTAGATTTTATGT 3370 TAGACA ATAC  7426  7448 CCGTATACATAAAATCT 1602 TTGTCTAGATTTTATGT 3371 AGACAA ATA  7466  7488 CCCCCCAAAGCTGGTTT 1603 GGCTTGAAACCAGCTT 3372 CAAGCC TGGG  7467  7489 CCCCCAAAGCTGGTTTC 1604 TGGCTTGAAACCAGCT 3373 AAGCCA TTGG  7468  7490 CCCCAAAGCTGGTTTCA 1605 TTGGCTTGAAACCAGC 3374 AGCCAA TTTG  7469  7491 CCCAAAGCTGGTTTCAA 1606 GTTGGCTTGAAACCAG 3375 GCCAAC CTTT  7470  7492 CCAAAGCTGGTTTCAAG 1607 GGTTGGCTTGAAACCA 3376 CCAACC GCTT  7487  7509 CCAACCCCATGGCCTCC 1608 AGTCATGGAGGCCATG 3377 ATGACT GGGT  7491  7513 CCCCATGGCCTCCATGA 1609 AAAAAGTCATGGAGG 3378 CTTTTT CCATG  7492  7514 CCCATGGCCTCCATGAC 1610 GAAAAAGTCATGGAG 3379 TTTTTC GCCAT  7493  7515 CCATGGCCTCCATGACT 1611 TGAAAAAGTCATGGA 3380 TTTTCA GGCCA  7499  7521 CCTCCATGACTTTTTCA 1612 CCTTTTTGAAAAAGTC 3381 AAAAGG ATGG  7502  7524 CCATGACTTTTTCAAAA 1613 ATACCTTTTTGAAAAA 3382 AGGTAT GTCA  7533  7555 CCATTTCATAACTTTGT 1614 ACTTTGACAAAGTTAT 3383 CAAAGT GAAA  7573  7595 CCTATATATCTTAATGG 1615 CATGTGCCATTAAGAT 3384 CACATG ATAT  7626  7648 CCCCTATCATAGAAGAG 1616 GATAAGCTCTTCTATG 3385 CTTATC ATAG  7627  7649 CCCTATCATAGAAGAGC 1617 TGATAAGCTCTTCTAT 3386 TTATCA GATA  7628  7650 CCTATCATAGAAGAGCT 1618 GTGATAAGCTCTTCTA 3387 TATCAC TGAT  7650  7672 CCTTTCATGATCACGCC 1619 TATGAGGGCGTGATCA 3388 CTCATA TGAA  7665  7687 CCCTCATAATCATTTTC 1620 GATAAGGAAAATGATT 3389 CTTATC ATGA  7666  7688 CCTCATAATCATTTTCCT 1621 AGATAAGGAAAATGA 3390 TATCT TTATG  7681  7703 CCTTATCTGCTTCCTAGT 1622 ACAGGACTAGGAAGC 3391 CCTGT AGATA  7693  7715 CCTAGTCCTGTATGCCC 1623 GGAAAAGGGCATACA 3392 TTTTCC GGACT  7699  7721 CCTGTATGCCCTTTTCCT 1624 GTGTTAGGAAAAGGG 3393 AACAC CATAC  7707  7729 CCCTTTTCCTAACACTC 1625 TGTTGTGAGTGTTAGG 3394 ACAACA AAAA  7708  7730 CCTTTTCCTAACACTCA 1626 TTGTTGTGAGTGTTAG 3395 CAACAA GAAA  7714  7736 CCTAACACTCACAACAA 1627 TTAGTTTTGTTGTGAG 3396 AACTAA TGTT  7773  7795 CCGTCTGAACTATCCTG 1628 GGCGGGCAGGATAGTT 3397 CCCGCC CAGA  7786  7808 CCTGCCCGCCATCATCC 1629 GGACTAGGATGATGGC 3398 TAGTCC GGGC  7790  7812 CCCGCCATCATCCTAGT 1630 ATGAGGACTAGGATG 3399 CCTCAT ATGGC  7791  7813 CCGCCATCATCCTAGTC 1631 GATGAGGACTAGGAT 3400 CTCATC GATGG  7794  7816 CCATCATCCTAGTCCTC 1632 GGCGATGAGGACTAG 3401 ATCGCC GATGA  7801  7823 CCTAGTCCTCATCGCCC 1633 ATGGGAGGGCGATGA 3402 TCCCAT GGACT  7807  7829 CCTCATCGCCCTCCCAT 1634 GTAGGGATGGGAGGG 3403 CCCTAC CGATG  7815  7837 CCCTCCCATCCCTACGC 1635 AAGGATGCGTAGGGA 3404 ATCCTT TGGGA  7816  7838 CCTCCCATCCCTACGCA 1636 AAAGGATGCGTAGGG 3405 TCCTTT ATGGG  7819  7841 CCCATCCCTACGCATCC 1637 TGTAAAGGATGCGTAG 3406 TTTACA GGAT  7820  7842 CCATCCCTACGCATCCT 1638 ATGTAAAGGATGCGTA 3407 TTACAT GGGA  7824  7846 CCCTACGCATCCTTTAC 1639 TGTTATGTAAAGGATG 3408 ATAACA CGTA  7825  7847 CCTACGCATCCTTTACA 1640 CTGTTATGTAAAGGAT 3409 TAACAG GCGT  7834  7856 CCTTTACATAACAGACG 1641 TGACCTCGTCTGTTAT 3410 AGGTCA GTAA  7862  7884 CCCTCCCTTACCATCAA 1642 ATTGATTTGATGGTAA 3411 ATCAAT GGGA  7863  7885 CCTCCCTTACCATCAAA 1643 AATTGATTTGATGGTA 3412 TCAATT AGGG  7866  7888 CCCTTACCATCAAATCA 1644 GCCAATTGATTTGATG 3413 ATTGGC GTAA  7867  7889 CCTTACCATCAAATCAA 1645 GGCCAATTGATTTGAT 3414 TTGGCC GGTA  7872  7894 CCATCAAATCAATTGGC 1646 TTGGTGGCCAATTGAT 3415 CACCAA TTGA  7888  7910 CCACCAATGGTACTGAA 1647 CGTAGGTTCAGTACCA 3416 CCTACG TTGG  7891  7913 CCAATGGTACTGAACCT 1648 ACTCGTAGGTTCAGTA 3417 ACGAGT CCAT  7905  7927 CCTACGAGTACACCGAC 1649 GCCGTAGTCGGTGTAC 3418 TACGGC TCGT  7917  7939 CCGACTACGGCGGACTA 1650 GAAGATTAGTCCGCCG 3419 ATCTTC TAGT  7944  7966 CCTACATACTTCCCCCA 1651 GAATAATGGGGGAAG 3420 TTATTC TATGT  7955  7977 CCCCCATTATTCCTAGA 1652 CCTGGTTCTAGGAATA 3421 ACCAGG ATGG  7956  7978 CCCCATTATTCCTAGAA 1653 GCCTGGTTCTAGGAAT 3422 CCAGGC AATG  7957  7979 CCCATTATTCCTAGAAC 1654 CGCCTGGTTCTAGGAA 3423 CAGGCG TAAT  7958  7980 CCATTATTCCTAGAACC 1655 TCGCCTGGTTCTAGGA 3424 AGGCGA ATAA  7966  7988 CCTAGAACCAGGCGACC 1656 GTCGCAGGTCGCCTGG 3425 TGCGAC TTCT  7973  7995 CCAGGCGACCTGCGACT 1657 TCAAGGAGTCGCAGGT 3426 CCTTGA CGCC  7981  8003 CCTGCGACTCCTTGACG 1658 TGTCAACGTCAAGGAG 3427 TTGACA TCGC  7990  8012 CCTTGACGTTGACAATC 1659 CTACTCGATTGTCAAC 3428 GAGTAG GTCA  8017  8039 CCCGATTGAAGCCCCCA 1660 TACGAATGGGGGCTTC 3429 TTCGTA AATC  8018  8040 CCGATTGAAGCCCCCAT 1661 ATACGAATGGGGGCTT 3430 TCGTAT CAAT  8028  8050 CCCCCATTCGTATAATA 1662 TGTAATTATTATACGA 3431 ATTACA ATGG  8029  8051 CCCCATTCGTATAATAA 1663 ATGTAATTATTATACG 3432 TTACAT AATG  8030  8052 CCCATTCGTATAATAAT 1664 GATGTAATTATTATAC 3433 TACATC GAAT  8031  8053 CCATTCGTATAATAATT 1665 TGATGTAATTATTATA 3434 ACATCA CGAA  8080  8102 CCCCACATTAGGCTTAA 1666 CTGTTTTTAAGCCTAA 3435 AAACAG TGTG  8081  8103 CCCACATTAGGCTTAAA 1667 TCTGTTTTTAAGCCTA 3436 AACAGA ATGT  8082  8104 CCACATTAGGCTTAAAA 1668 ATCTGTTTTTAAGCCT 3437 ACAGAT AATG  8111  8133 CCCGGACGTCTAAACCA 1669 GTGGTTTGGTTTAGAC 3438 AACCAC GTCC  8112  8134 CCGGACGTCTAAACCAA 1670 AGTGGTTTGGTTTAGA 3439 ACCACT CGTC  8125  8147 CCAAACCACTTTCACCG 1671 GTGTAGCGGTGAAAGT 3440 CTACAC GGTT  8130  8152 CCACTTTCACCGCTACA 1672 CGGTCGTGTAGCGGTG 3441 CGACCG AAAG  8139  8161 CCGCTACACGACCGGGG 1673 GTATACCCCCGGTCGT 3442 GTATAC GTAG  8150  8172 CCGGGGGTATACTACGG 1674 CATTGACCGTAGTATA 3443 TCAATG CCCC  8194  8216 CCACAGTTTCATGCCCA 1675 GGACGATGGGCATGA 3444 TCGTCC AACTG  8207  8229 CCCATCGTCCTAGAATT 1676 GGAATTAATTCTAGGA 3445 AATTCC CGAT  8208  8230 CCATCGTCCTAGAATTA 1677 GGGAATTAATTCTAGG 3446 ATTCCC ACGA  8215  8237 CCTAGAATTAATTCCCC 1678 TTTTTAGGGGAATTAA 3447 TAAAAA TTCT  8228  8250 CCCCTAAAAATCTTTGA 1679 CCTATTTCAAAGATTT 3448 AATAGG TTAG  8229  8251 CCCTAAAAATCTTTGAA 1680 CCCTATTTCAAAGATT 3449 ATAGGG TTTA  8230  8252 CCTAAAAATCTTTGAAA 1681 GCCCTATTTCAAAGAT 3450 TAGGGC TTTT  8252  8274 CCCGTATTTACCCTATA 1682 GGGTGCTATAGGGTAA 3451 GCACCC ATAC  8253  8275 CCGTATTTACCCTATAG 1683 GGGGTGCTATAGGGTA 3452 CACCCC AATA  8262  8284 CCCTATAGCACCCCCTC 1684 GGGGTAGAGGGGGTG 3453 TACCCC CTATA  8263  8285 CCTATAGCACCCCCTCT 1685 GGGGGTAGAGGGGGT 3454 ACCCCC GCTAT  8272  8294 CCCCCTCTACCCCCTCT 1686 GGCTCTAGAGGGGGTA 3455 AGAGCC GAGG  8273  8295 CCCCTCTACCCCCTCTA 1687 GGGCTCTAGAGGGGGT 3456 GAGCCC AGAG  8274  8296 CCCTCTACCCCCTCTAG 1688 TGGGCTCTAGAGGGGG 3457 AGCCCA TAGA  8275  8297 CCTCTACCCCCTCTAGA 1689 GTGGGCTCTAGAGGGG 3458 GCCCAC GTAG  8281  8303 CCCCCTCTAGAGCCCAC 1690 TTTACAGTGGGCTCTA 3459 TGTAAA GAGG  8282  8304 CCCCTCTAGAGCCCACT 1691 CTTTACAGTGGGCTCT 3460 GTAAAG AGAG  8283  8305 CCCTCTAGAGCCCACTG 1692 GCTTTACAGTGGGCTC 3461 TAAAGC TAGA  8284  8306 CCTCTAGAGCCCACTGT 1693 AGCTTTACAGTGGGCT 3462 AAAGCT CTAG  8293  8315 CCCACTGTAAAGCTAAC 1694 TGCTAAGTTAGCTTTA 3463 TTAGCA CAGT  8294  8316 CCACTGTAAAGCTAACT 1695 ATGCTAAGTTAGCTTT 3464 TAGCAT ACAG  8320  8342 CCTTTTAAGTTAAAGAT 1696 CTCTTAATCTTTAACTT 3465 TAAGAG AAA  8345  8367 CCAACACCTCTTTACAG 1697 ATTTCACTGTAAAGAG 3466 TGAAAT GTGT  8351  8373 CCTCTTTACAGTGAAAT 1698 TGGGGCATTTCACTGT 3467 GCCCCA AAAG  8369  8391 CCCCAACTAAATACTAC 1699 CATACGGTAGTATTTA 3468 CGTATG GTTG  8370  8392 CCCAACTAAATACTACC 1700 CCATACGGTAGTATTT 3469 GTATGG AGTT  8371  8393 CCAACTAAATACTACCG 1701 GCCATACGGTAGTATT 3470 TATGGC TAGT  8385  8407 CCGTATGGCCCACCATA 1702 GGTAATTATGGTGGGC 3471 ATTACC CATA  8393  8415 CCCACCATAATTACCCC 1703 AGTATGGGGGTAATTA 3472 CATACT TGGT  8394  8416 CCACCATAATTACCCCC 1704 GAGTATGGGGGTAATT 3473 ATACTC ATGG  8397  8419 CCATAATTACCCCCATA 1705 AAGGAGTATGGGGGT 3474 CTCCTT AATTA  8406  8428 CCCCCATACTCCTTACA 1706 GAATAGTGTAAGGAGT 3475 CTATTC ATGG  8407  8429 CCCCATACTCCTTACAC 1707 GGAATAGTGTAAGGA 3476 TATTCC GTATG  8408  8430 CCCATACTCCTTACACT 1708 AGGAATAGTGTAAGG 3477 ATTCCT AGTAT  8409  8431 CCATACTCCTTACACTA 1709 GAGGAATAGTGTAAG 3478 TTCCTC GAGTA  8416  8438 CCTTACACTATTCCTCA 1710 GGGTGATGAGGAATA 3479 TCACCC GTGTA  8428  8450 CCTCATCACCCAACTAA 1711 ATATTTTTAGTTGGGT 3480 AAATAT GATG  8436  8458 CCCAACTAAAAATATTA 1712 TGTGTTTAATATTTTTA 3481 AACACA GTT  8437  8459 CCAACTAAAAATATTAA 1713 TTGTGTTTAATATTTTT 3482 ACACAA AGT  8464  8486 CCACCTACCTCCCTCAC 1714 GCTTTGGTGAGGGAGG 3483 CAAAGC TAGG  8467  8489 CCTACCTCCCTCACCAA 1715 TGGGCTTTGGTGAGGG 3484 AGCCCA AGGT  8471  8493 CCTCCCTCACCAAAGCC 1716 TTTATGGGCTTTGGTG 3485 CATAAA AGGG  8474  8496 CCCTCACCAAAGCCCAT 1717 ATTTTTATGGGCTTTG 3486 AAAAAT GTGA  8475  8497 CCTCACCAAAGCCCATA 1718 TATTTTTATGGGCTTTG 3487 AAAATA GTG  8480  8502 CCAAAGCCCATAAAAAT 1719 TTTTTTATTTTTATGGG 3488 AAAAAA CTT  8486  8508 CCCATAAAAATAAAAA 1720 TTATAATTTTTTATTTT 3489 ATTATAA TAT  8487  8509 CCATAAAAATAAAAAA 1721 GTTATAATTTTTTATTT 3490 TTATAAC TTA  8513  8535 CCCTGAGAACCAAAATG 1722 TTCGTTCATTTTGGTTC 3491 AACGAA TCA  8514  8536 CCTGAGAACCAAAATG 1723 TTTCGTTCATTTTGGTT 3492 AACGAAA CTC  8522  8544 CCAAAATGAACGAAAA 1724 GAACAGATTTTCGTTC 3493 TCTGTTC ATTT  8558  8580 CCCCCACAATCCTAGGC 1725 GGGTAGGCCTAGGATT 3494 CTACCC GTGG  8559  8581 CCCCACAATCCTAGGCC 1726 CGGGTAGGCCTAGGAT 3495 TACCCG TGTG  8560  8582 CCCACAATCCTAGGCCT 1727 GCGGGTAGGCCTAGG 3496 ACCCGC ATTGT  8561  8583 CCACAATCCTAGGCCTA 1728 GGCGGGTAGGCCTAG 3497 CCCGCC GATTG  8568  8590 CCTAGGCCTACCCGCCG 1729 GTACTGCGGCGGGTAG 3498 CAGTAC GCCT  8574  8596 CCTACCCGCCGCAGTAC 1730 TGATCAGTACTGCGGC 3499 TGATCA GGGT  8578  8600 CCCGCCGCAGTACTGAT 1731 AGAATGATCAGTACTG 3500 CATTCT CGGC  8579  8601 CCGCCGCAGTACTGATC 1732 TAGAATGATCAGTACT 3501 ATTCTA GCGG  8582  8604 CCGCAGTACTGATCATT 1733 AAATAGAATGATCAGT 3502 CTATTT ACTG  8605  8627 CCCCCTCTATTGATCCC 1734 GAGGTGGGGATCAAT 3503 CACCTC AGAGG  8606  8628 CCCCTCTATTGATCCCC 1735 GGAGGTGGGGATCAA 3504 ACCTCC TAGAG  8607  8629 CCCTCTATTGATCCCCA 1736 TGGAGGTGGGGATCA 3505 CCTCCA ATAGA  8608  8630 CCTCTATTGATCCCCAC 1737 TTGGAGGTGGGGATCA 3506 CTCCAA ATAG  8619  8641 CCCCACCTCCAAATATC 1738 TGATGAGATATTTGGA 3507 TCATCA GGTG  8620  8642 CCCACCTCCAAATATCT 1739 TTGATGAGATATTTGG 3508 CATCAA AGGT  8621  8643 CCACCTCCAAATATCTC 1740 GTTGATGAGATATTTG 3509 ATCAAC GAGG  8624  8646 CCTCCAAATATCTCATC 1741 GTTGTTGATGAGATAT 3510 AACAAC TTGG  8627  8649 CCAAATATCTCATCAAC 1742 TCGGTTGTTGATGAGA 3511 AACCGA TATT  8646  8668 CCGACTAATCACCACCC 1743 ATTGTTGGGTGGTGAT 3512 AACAAT TAGT  8657  8679 CCACCCAACAATGACTA 1744 TTTGATTAGTCATTGTT 3513 ATCAAA GGG  8660  8682 CCCAACAATGACTAATC 1745 TAGTTTGATTAGTCAT 3514 AAACTA TGTT  8661  8683 CCAACAATGACTAATCA 1746 TTAGTTTGATTAGTCA 3515 AACTAA TTGT  8684  8706 CCTCAAAACAAATGATA 1747 TATGGTTATCATTTGTT 3516 ACCATA TTG  8702  8724 CCATACACAACACTAAA 1748 TCGTCCTTTAGTGTTGT 3517 GGACGA GTA  8726  8748 CCTGATCTCTTATACTA 1749 GGATACTAGTATAAGA 3518 GTATCC GATC  8747  8769 CCTTAATCATTTTTATTG 1750 TGTGGCAATAAAAATG 3519 CCACA ATTA  8765  8787 CCACAACTAACCTCCTC 1751 GAGTCCGAGGAGGTTA 3520 GGACTC GTTG  8775  8797 CCTCCTCGGACTCCTGC 1752 AGTGAGGCAGGAGTC 3521 CTCACT CGAGG  8778  8800 CCTCGGACTCCTGCCTC 1753 ATGAGTGAGGCAGGA 3522 ACTCAT GTCCG  8787  8809 CCTGCCTCACTCATTTA 1754 TTGGTGTAAATGAGTG 3523 CACCAA AGGC  8791  8813 CCTCACTCATTTACACC 1755 GTGGTTGGTGTAAATG 3524 AACCAC AGTG  8806  8828 CCAACCACCCAACTATC 1756 TTTATAGATAGTTGGG 3525 TATAAA TGGT  8810  8832 CCACCCAACTATCTATA 1757 TAGGTTTATAGATAGT 3526 AACCTA TGGG  8813  8835 CCCAACTATCTATAAAC 1758 GGCTAGGTTTATAGAT 3527 CTAGCC AGTT  8814  8836 CCAACTATCTATAAACC 1759 TGGCTAGGTTTATAGA 3528 TAGCCA TAGT  8829  8851 CCTAGCCATGGCCATCC 1760 ATAAGGGGATGGCCAT 3529 CCTTAT GGCT  8834  8856 CCATGGCCATCCCCTTA 1761 CGCTCATAAGGGGATG 3530 TGAGCG GCCA  8840  8862 CCATCCCCTTATGAGCG 1762 TGTGCCCGCTCATAAG 3531 GGCACA GGGA  8844  8866 CCCCTTATGAGCGGGCA 1763 TCACTGTGCCCGCTCA 3532 CAGTGA TAAG  8845  8867 CCCTTATGAGCGGGCAC 1764 ATCACTGTGCCCGCTC 3533 AGTGAT ATAA  8846  8868 CCTTATGAGCGGGCACA 1765 AATCACTGTGCCCGCT 3534 GTGATT CATA  8897  8919 CCCTAGCCCACTTCTTA 1766 TTGTGGTAAGAAGTGG 3535 CCACAA GCTA  8898  8920 CCTAGCCCACTTCTTAC 1767 CTTGTGGTAAGAAGTG 3536 CACAAG GGCT  8903  8925 CCCACTTCTTACCACAA 1768 TGTGCCTTGTGGTAAG 3537 GGCACA AAGT  8904  8926 CCACTTCTTACCACAAG 1769 GTGTGCCTTGTGGTAA 3538 GCACAC GAAG  8914  8936 CCACAAGGCACACCTAC 1770 AGGGGTGTAGGTGTGC 3539 ACCCCT CTTG  8926  8948 CCTACACCCCTTATCCC 1771 AGTATGGGGATAAGG 3540 CATACT GGTGT  8932  8954 CCCCTTATCCCCATACT 1772 ATAACTAGTATGGGGA 3541 AGTTAT TAAG  8933  8955 CCCTTATCCCCATACTA 1773 AATAACTAGTATGGGG 3542 GTTATT ATAA  8934  8956 CCTTATCCCCATACTAG 1774 TAATAACTAGTATGGG 3543 TTATTA GATA  8940  8962 CCCCATACTAGTTATTA 1775 TTTCGATAATAACTAG 3544 TCGAAA TATG  8941  8963 CCCATACTAGTTATTAT 1776 GTTTCGATAATAACTA 3545 CGAAAC GTAT  8942  8964 CCATACTAGTTATTATC 1777 GGTTTCGATAATAACT 3546 GAAACC AGTA  8963  8985 CCATCAGCCTACTCATT 1778 TGGTTGAATGAGTAGG 3547 CAACCA CTGA  8970  8992 CCTACTCATTCAACCAA 1779 GGGCTATTGGTTGAAT 3548 TAGCCC GAGT  8983  9005 CCAATAGCCCTGGCCGT 1780 AGGCGTACGGCCAGG 3549 ACGCCT GCTAT  8990  9012 CCCTGGCCGTACGCCTA 1781 AGCGGTTAGGCGTACG 3550 ACCGCT GCCA  8991  9013 CCTGGCCGTACGCCTAA 1782 TAGCGGTTAGGCGTAC 3551 CCGCTA GGCC  8996  9018 CCGTACGCCTAACCGCT 1783 AATGTTAGCGGTTAGG 3552 AACATT CGTA  9003  9025 CCTAACCGCTAACATTA 1784 CTGCAGTAATGTTAGC 3553 CTGCAG GGTT  9008  9030 CCGCTAACATTACTGCA 1785 GTGGCCTGCAGTAATG 3554 GGCCAC TTAG  9027  9049 CCACCTACTCATGCACC 1786 CAATTAGGTGCATGAG 3555 TAATTG TAGG  9030  9052 CCTACTCATGCACCTAA 1787 TTCCAATTAGGTGCAT 3556 TTGGAA GAGT  9042  9064 CCTAATTGGAAGCGCCA 1788 CTAGGGTGGCGCTTCC 3557 CCCTAG AATT  9056  9078 CCACCCTAGCAATATCA 1789 AATGGTTGATATTGCT 3558 ACCATT AGGG  9059  9081 CCCTAGCAATATCAACC 1790 GTTAATGGTTGATATT 3559 ATTAAC GCTA  9060  9082 CCTAGCAATATCAACCA 1791 GGTTAATGGTTGATAT 3560 TTAACC TGCT  9074  9096 CCATTAACCTTCCCTCT 1792 AAGTGTAGAGGGAAG 3561 ACACTT GTTAA  9081  9103 CCTTCCCTCTACACTTAT 1793 AGATGATAAGTGTAGA 3562 CATCT GGGA  9085  9107 CCCTCTACACTTATCAT 1794 GTGAAGATGATAAGTG 3563 CTTCAC TAGA  9086  9108 CCTCTACACTTATCATC 1795 TGTGAAGATGATAAGT 3564 TTCACA GTAG  9129  9151 CCTAGAAATCGCTGTCG 1796 TTAAGGCGACAGCGAT 3565 CCTTAA TTCT  9146  9168 CCTTAATCCAAGCCTAC 1797 GAAAACGTAGGCTTGG 3566 GTTTTC ATTA  9153  9175 CCAAGCCTACGTTTTCA 1798 GAAGTGTGAAAACGT 3567 CACTTC AGGCT  9158  9180 CCTACGTTTTCACACTT 1799 TACTAGAAGTGTGAAA 3568 CTAGTA ACGT  9183  9205 CCTCTACCTGCACGACA 1800 ATGTGTTGTCGTGCAG 3569 ACACAT GTAG  9189  9211 CCTGCACGACAACACAT 1801 GTCATTATGTGTTGTC 3570 AATGAC GTGC  9211  9233 CCCACCAATCACATGCC 1802 ATGATAGGCATGTGAT 3571 TATCAT TGGT  9212  9234 CCACCAATCACATGCCT 1803 TATGATAGGCATGTGA 3572 ATCATA TTGG  9215  9237 CCAATCACATGCCTATC 1804 CTATATGATAGGCATG 3573 ATATAG TGAT  9226  9248 CCTATCATATAGTAAAA 1805 GCTGGGTTTTACTATA 3574 CCCAGC TGAT  9243  9265 CCCAGCCCATGACCCCT 1806 CCTGTTAGGGGTCATG 3575 AACAGG GGCT  9244  9266 CCAGCCCATGACCCCTA 1807 CCCTGTTAGGGGTCAT 3576 ACAGGG GGGC  9248  9270 CCCATGACCCCTAACAG 1808 GGGCCCCTGTTAGGGG 3577 GGGCCC TCAT  9249  9271 CCATGACCCCTAACAGG 1809 AGGGCCCCTGTTAGGG 3578 GGCCCT GTCA  9255  9277 CCCCTAACAGGGGCCCT 1810 GCTGAGAGGGCCCCTG 3579 CTCAGC TTAG  9256  9278 CCCTAACAGGGGCCCTC 1811 GGCTGAGAGGGCCCCT 3580 TCAGCC GTTA  9257  9279 CCTAACAGGGGCCCTCT 1812 GGGCTGAGAGGGCCC 3581 CAGCCC CTGTT  9268  9290 CCCTCTCAGCCCTCCTA 1813 GGTCATTAGGAGGGCT 3582 ATGACC GAGA  9269  9291 CCTCTCAGCCCTCCTAA 1814 AGGTCATTAGGAGGGC 3583 TGACCT TGAG  9277  9299 CCCTCCTAATGACCTCC 1815 TAGGCCGGAGGTCATT 3584 GGCCTA AGGA  9278  9300 CCTCCTAATGACCTCCG 1816 CTAGGCCGGAGGTCAT 3585 GCCTAG TAGG  9281  9303 CCTAATGACCTCCGGCC 1817 TGGCTAGGCCGGAGGT 3586 TAGCCA CATT  9289  9311 CCTCCGGCCTAGCCATG 1818 AAATCACATGGCTAGG 3587 TGATTT CCGG  9292  9314 CCGGCCTAGCCATGTGA 1819 GTGAAATCACATGGCT 3588 TTTCAC AGGC  9296  9318 CCTAGCCATGTGATTTC 1820 GGAAGTGAAATCACAT 3589 ACTTCC GGCT  9301  9323 CCATGTGATTTCACTTC 1821 GGAGTGGAAGTGAAA 3590 CACTCC TCACA  9317  9339 CCACTCCATAACGCTCC 1822 GTATGAGGAGCGTTAT 3591 TCATAC GGAG  9322  9344 CCATAACGCTCCTCATA 1823 GCCTAGTATGAGGAGC 3592 CTAGGC GTTA  9332  9354 CCTCATACTAGGCCTAC 1824 TGGTTAGTAGGCCTAG 3593 TAACCA TATG  9344  9366 CCTACTAACCAACACAC 1825 TGGTTAGTGTGTTGGT 3594 TAACCA TAGT  9352  9374 CCAACACACTAACCATA 1826 TTGGTATATGGTTAGT 3595 TACCAA GTGT  9364  9386 CCATATACCAATGATGG 1827 ATCGCGCCATCATTGG 3596 CGCGAT TATA  9371  9393 CCAATGATGGCGCGATG 1828 GTGTTACATCGCGCCA 3597 TAACAC TCAT  9407  9429 CCAAGGCCACCACACAC 1829 CAGGTGGTGTGTGGTG 3598 CACCTG GCCT  9413  9435 CCACCACACACCACCTG 1830 TTTGGACAGGTGGTGT 3599 TCCAAA GTGG  9416  9438 CCACACACCACCTGTCC 1831 CTTTTTGGACAGGTGG 3600 AAAAAG TGTG  9423  9445 CCACCTGTCCAAAAAGG 1832 CGAAGGCCTTTTTGGA 3601 CCTTCG CAGG  9426  9448 CCTGTCCAAAAAGGCCT 1833 TATCGAAGGCCTTTTT 3602 TCGATA GGAC  9431  9453 CCAAAAAGGCCTTCGAT 1834 TCCCGTATCGAAGGCC 3603 ACGGGA TTTT  9440  9462 CCTTCGATACGGGATAA 1835 ATAGGATTATCCCGTA 3604 TCCTAT TCGA  9458  9480 CCTATTTATTACCTCAG 1836 AAACTTCTGAGGTAAT 3605 AAGTTT AAAT  9469  9491 CCTCAGAAGTTTTTTTCT 1837 TGCGAAGAAAAAAAC 3606 TCGCA TTCTG  9505  9527 CCTTTTACCACTCCAGC 1838 GGCTAGGCTGGAGTGG 3607 CTAGCC TAAA  9512  9534 CCACTCCAGCCTAGCCC 1839 GGGTAGGGGCTAGGCT 3608 CTACCC GGAG  9517  9539 CCAGCCTAGCCCCTACC 1840 TTGGGGGGTAGGGGCT 3609 CCCCAA AGGC  9521  9543 CCTAGCCCCTACCCCCC 1841 CTAATTGGGGGGTAGG 3610 AATTAG GGCT  9526  9548 CCCCTACCCCCCAATTA 1842 CCCTCCTAATTGGGGG 3611 GGAGGG GTAG  9527  9549 CCCTACCCCCCAATTAG 1843 GCCCTCCTAATTGGGG 3612 GAGGGC GGTA  9528  9550 CCTACCCCCCAATTAGG 1844 TGCCCTCCTAATTGGG 3613 AGGGCA GGGT  9532  9554 CCCCCCAATTAGGAGGG 1845 CCAGTGCCCTCCTAAT 3614 CACTGG TGGG  9533  9555 CCCCCAATTAGGAGGGC 1846 GCCAGTGCCCTCCTAA 3615 ACTGGC TTGG  9534  9556 CCCCAATTAGGAGGGCA 1847 GGCCAGTGCCCTCCTA 3616 CTGGCC ATTG  9535  9557 CCCAATTAGGAGGGCAC 1848 GGGCCAGTGCCCTCCT 3617 TGGCCC AATT  9536  9558 CCAATTAGGAGGGCACT 1849 GGGGCCAGTGCCCTCC 3618 GGCCCC TAAT  9555  9577 CCCCCAACAGGCATCAC 1850 AGCGGGGTGATGCCTG 3619 CCCGCT TTGG  9556  9578 CCCCAACAGGCATCACC 1851 TAGCGGGGTGATGCCT 3620 CCGCTA GTTG  9557  9579 CCCAACAGGCATCACCC 1852 TTAGCGGGGTGATGCC 3621 CGCTAA TGTT  9558  9580 CCAACAGGCATCACCCC 1853 TTTAGCGGGGTGATGC 3622 GCTAAA CTGT  9571  9593 CCCCGCTAAATCCCCTA 1854 GACTTCTAGGGGATTT 3623 GAAGTC AGCG  9572  9594 CCCGCTAAATCCCCTAG 1855 GGACTTCTAGGGGATT 3624 AAGTCC TAGC  9573  9595 CCGCTAAATCCCCTAGA 1856 GGGACTTCTAGGGGAT 3625 AGTCCC TTAG  9582  9604 CCCCTAGAAGTCCCACT 1857 TTTAGGAGTGGGACTT 3626 CCTAAA CTAG  9583  9605 CCCTAGAAGTCCCACTC 1858 GTTTAGGAGTGGGACT 3627 CTAAAC TCTA  9584  9606 CCTAGAAGTCCCACTCC 1859 TGTTTAGGAGTGGGAC 3628 TAAACA TTCT  9593  9615 CCCACTCCTAAACACAT 1860 ATACGGATGTGTTTAG 3629 CCGTAT GAGT  9594  9616 CCACTCCTAAACACATC 1861 AATACGGATGTGTTTA 3630 CGTATT GGAG  9599  9621 CCTAAACACATCCGTAT 1862 CGAGTAATACGGATGT 3631 TACTCG GTTT  9610  9632 CCGTATTACTCGCATCA 1863 TACTCCTGATGCGAGT 3632 GGAGTA AATA  9640  9662 CCTGAGCTCACCATAGT 1864 TATTAGACTATGGTGA 3633 CTAATA GCTC  9650  9672 CCATAGTCTAATAGAAA 1865 GGTTGTTTTCTATTAG 3634 ACAACC ACTA  9671  9693 CCGAAACCAAATAATTC 1866 GTGCTTGAATTATTTG 3635 AAGCAC GTTT  9677  9699 CCAAATAATTCAAGCAC 1867 TAAGCAGTGCTTGAAT 3636 TGCTTA TATT  9727  9749 CCCTCCTACAAGCCTCA 1868 GTACTCTGAGGCTTGT 3637 GAGTAC AGGA  9728  9750 CCTCCTACAAGCCTCAG 1869 AGTACTCTGAGGCTTG 3638 AGTACT TAGG  9731  9753 CCTACAAGCCTCAGAGT 1870 CGAAGTACTCTGAGGC 3639 ACTTCG TTGT  9739  9761 CCTCAGAGTACTTCGAG 1871 GGGAGACTCGAAGTA 3640 TCTCCC CTCTG  9759  9781 CCCTTCACCATTTCCGA 1872 ATGCCGTCGGAAATGG 3641 CGGCAT TGAA  9760  9782 CCTTCACCATTTCCGAC 1873 GATGCCGTCGGAAATG 3642 GGCATC GTGA  9766  9788 CCATTTCCGACGGCATC 1874 GCCGTAGATGCCGTCG 3643 TACGGC GAAA  9772  9794 CCGACGGCATCTACGGC 1875 TGTTGAGCCGTAGATG 3644 TCAACA CCGT  9805  9827 CCACAGGCTTCCACGGA 1876 GTGAAGTCCGTGGAAG 3645 CTTCAC CCTG  9815  9837 CCACGGACTTCACGTCA 1877 CAATAATGACGTGAAG 3646 TTATTG TCCG  9848  9870 CCTCACTATCTGCTTCA 1878 GGCGGATGAAGCAGA 3647 TCCGCC TAGTG  9866  9888 CCGCCAACTAATATTTC 1879 TAAAGTGAAATATTAG 3648 ACTTTA TTGG  9869  9891 CCAACTAATATTTCACT 1880 ATGTAAAGTGAAATAT 3649 TTACAT TAGT  9892  9914 CCAAACATCACTTTGGC 1881 TTCGAAGCCAAAGTGA 3650 TTCGAA TGTT  9916  9938 CCGCCGCCTGATACTGG 1882 AAAATGCCAGTATCAG 3651 CATTTT GCGG  9919  9941 CCGCCTGATACTGGCAT 1883 TACAAAATGCCAGTAT 3652 TTTGTA CAGG  9922  9944 CCTGATACTGGCATTTT 1884 ATCTACAAAATGCCAG 3653 GTAGAT TATC  9970  9992 CCATCTATTGATGAGGG 1885 GTAAGACCCTCATCAA 3654 TCTTAC TAGA 10012 10034 CCGTTAACTTCCAATTA 1886 ACTAGTTAATTGGAAG 3655 ACTAGT TTAA 10022 10044 CCAATTAACTAGTTTTG 1887 TGTTGTCAAAACTAGT 3656 ACAACA TAAT 10069 10091 CCTTAATTTTAATAATC 1888 GGTGTTGATTATTAAA 3657 AACACC ATTA 10090 10112 CCCTCCTAGCCTTACTA 1889 TATTAGTAGTAAGGCT 3658 CTAATA AGGA 10091 10113 CCTCCTAGCCTTACTAC 1890 TTATTAGTAGTAAGGC 3659 TAATAA TAGG 10094 10116 CCTAGCCTTACTACTAA 1891 TAATTATTAGTAGTAA 3660 TAATTA GGCT 10099 10121 CCTTACTACTAATAATT 1892 TGTAATAATTATTAGT 3661 ATTACA AGTA 10131 10153 CCACAACTCAACGGCTA 1893 TCTATGTAGCCGTTGA 3662 CATAGA GTTG 10159 10181 CCACCCCTTACGAGTGC 1894 GAAGCCGCACTCGTAA 3663 GGCTTC GGGG 10162 10184 CCCCTTACGAGTGCGGC 1895 GTCGAAGCCGCACTCG 3664 TTCGAC TAAG 10163 10185 CCCTTACGAGTGCGGCT 1896 GGTCGAAGCCGCACTC 3665 TCGACC GTAA 10164 10186 CCTTACGAGTGCGGCTT 1897 GGGTCGAAGCCGCACT 3666 CGACCC CGTA 10184 10206 CCCTATATCCCCCGCCC 1898 GGACGCGGGCGGGGG 3667 GCGTCC ATATA 10185 10207 CCTATATCCCCCGCCCG 1899 GGGACGCGGGCGGGG 3668 CGTCCC GATAT 10192 10214 CCCCCGCCCGCGTCCCT 1900 GGAGAAAGGGACGCG 3669 TTCTCC GGCGG 10193 10215 CCCCGCCCGCGTCCCTT 1901 TGGAGAAAGGGACGC 3670 TCTCCA GGGCG 10194 10216 CCCGCCCGCGTCCCTTT 1902 ATGGAGAAAGGGACG 3671 CTCCAT CGGGC 10195 10217 CCGCCCGCGTCCCTTTC 1903 TATGGAGAAAGGGAC 3672 TCCATA GCGGG 10198 10220 CCCGCGTCCCTTTCTCC 1904 TTTTATGGAGAAAGGG 3673 ATAAAA ACGC 10199 10221 CCGCGTCCCTTTCTCCA 1905 ATTTTATGGAGAAAGG 3674 TAAAAT GACG 10205 10227 CCCTTTCTCCATAAAAT 1906 AGAAGAATTTTATGGA 3675 TCTTCT GAAA 10206 10228 CCTTTCTCCATAAAATT 1907 AAGAAGAATTTTATGG 3676 CTTCTT AGAA 10213 10235 CCATAAAATTCTTCTTA 1908 AGCTACTAAGAAGAAT 3677 GTAGCT TTTA 10240 10262 CCTTCTTATTATTTGATC 1909 TTCTAGATCAAATAAT 3678 TAGAA AAGA 10267 10289 CCCTCCTTTTACCCCTAC 1910 TCATGGTAGGGGTAAA 3679 CATGA AGGA 10268 10290 CCTCCTTTTACCCCTACC 1911 CTCATGGTAGGGGTAA 3680 ATGAG AAGG 10271 10293 CCTTTTACCCCTACCAT 1912 GGGCTCATGGTAGGGG 3681 GAGCCC TAAA 10278 10300 CCCCTACCATGAGCCCT 1913 GTTTGTAGGGCTCATG 3682 ACAAAC GTAG 10279 10301 CCCTACCATGAGCCCTA 1914 TGTTTGTAGGGCTCAT 3683 CAAACA GGTA 10280 10302 CCTACCATGAGCCCTAC 1915 TTGTTTGTAGGGCTCA 3684 AAACAA TGGT 10284 10306 CCATGAGCCCTACAAAC 1916 TTAGTTGTTTGTAGGG 3685 AACTAA CTCA 10291 10313 CCCTACAAACAACTAAC 1917 TGGCAGGTTAGTTGTT 3686 CTGCCA TGTA 10292 10314 CCTACAAACAACTAACC 1918 GTGGCAGGTTAGTTGT 3687 TGCCAC TTGT 10307 10329 CCTGCCACTAATAGTTA 1919 ATGACATAACTATTAG 3688 TGTCAT TGGC 10311 10333 CCACTAATAGTTATGTC 1920 AGGGATGACATAACTA 3689 ATCCCT TTAG 10330 10352 CCCTCTTATTAATCATC 1921 TAGGATGATGATTAAT 3690 ATCCTA AAGA 10331 10353 CCTCTTATTAATCATCA 1922 CTAGGATGATGATTAA 3691 TCCTAG TAAG 10349 10371 CCTAGCCCTAAGTCTGG 1923 CATAGGCCAGACTTAG 3692 CCTATG GGCT 10354 10376 CCCTAAGTCTGGCCTAT 1924 TCACTCATAGGCCAGA 3693 GAGTGA CTTA 10355 10377 CCTAAGTCTGGCCTATG 1925 GTCACTCATAGGCCAG 3694 AGTGAC ACTT 10366 10388 CCTATGAGTGACTACAA 1926 TCCTTTTTGTAGTCACT 3695 AAAGGA CAT 10399 10421 CCGAATTGGTATATAGT 1927 GTTTAAACTATATACC 3696 TTAAAC AATT 10466 10488 CCAAATGCCCCTCATTT 1928 TTATGTAAATGAGGGG 3697 ACATAA CATT 10473 10495 CCCCTCATTTACATAAA 1929 ATAATATTTATGTAAA 3698 TATTAT TGAG 10474 10496 CCCTCATTTACATAAAT 1930 TATAATATTTATGTAA 3699 ATTATA ATGA 10475 10497 CCTCATTTACATAAATA 1931 GTATAATATTTATGTA 3700 TTATAC AATG 10507 10529 CCATCTCACTTCTAGGA 1932 TAGTATTCCTAGAAGT 3701 ATACTA GAGA 10544 10566 CCTCATATCCTCCCTAC 1933 GGCATAGTAGGGAGG 3702 TATGCC ATATG 10552 10574 CCTCCCTACTATGCCTA 1934 TCCTTCTAGGCATAGT 3703 GAAGGA AGGG 10555 10577 CCCTACTATGCCTAGAA 1935 TATTCCTTCTAGGCAT 3704 GGAATA AGTA 10556 10578 CCTACTATGCCTAGAAG 1936 TTATTCCTTCTAGGCA 3705 GAATAA TAGT 10565 10587 CCTAGAAGGAATAATAC 1937 GCGATAGTATTATTCC 3706 TATCGC TTCT 10612 10634 CCCTCAACACCCACTCC 1938 TAAGAGGGAGTGGGT 3707 CTCTTA GTTGA 10613 10635 CCTCAACACCCACTCCC 1939 CTAAGAGGGAGTGGG 3708 TCTTAG TGTTG 10621 10643 CCCACTCCCTCTTAGCC 1940 AATATTGGCTAAGAGG 3709 AATATT GAGT 10622 10644 CCACTCCCTCTTAGCCA 1941 CAATATTGGCTAAGAG 3710 ATATTG GGAG 10627 10649 CCCTCTTAGCCAATATT 1942 AGGCACAATATTGGCT 3711 GTGCCT AAGA 10628 10650 CCTCTTAGCCAATATTG 1943 TAGGCACAATATTGGC 3712 TGCCTA TAAG 10636 10658 CCAATATTGTGCCTATT 1944 TATGGCAATAGGCACA 3713 GCCATA ATAT 10647 10669 CCTATTGCCATACTAGT 1945 GCAAAGACTAGTATGG 3714 CTTTGC CAAT 10654 10676 CCATACTAGTCTTTGCC 1946 GCAGGCGGCAAAGAC 3715 GCCTGC TAGTA 10669 10691 CCGCCTGCGAAGCAGCG 1947 GCCCACCGCTGCTTCG 3716 GTGGGC CAGG 10672 10694 CCTGCGAAGCAGCGGTG 1948 TAGGCCCACCGCTGCT 3717 GGCCTA TCGC 10691 10713 CCTAGCCCTACTAGTCT 1949 AGATTGAGACTAGTAG 3718 CAATCT GGCT 10696 10718 CCCTACTAGTCTCAATC 1950 GTTGGAGATTGAGACT 3719 TCCAAC AGTA 10697 10719 CCTACTAGTCTCAATCT 1951 TGTTGGAGATTGAGAC 3720 CCAACA TAGT 10714 10736 CCAACACATATGGCCTA 1952 GTAGTCTAGGCCATAT 3721 GACTAC GTGT 10727 10749 CCTAGACTACGTACATA 1953 TTAGGTTATGTACGTA 3722 ACCTAA GTCT 10745 10767 CCTAAACCTACTCCAAT 1954 TTTAGCATTGGAGTAG 3723 GCTAAA GTTT 10751 10773 CCTACTCCAATGCTAAA 1955 ATTAGTTTTAGCATTG 3724 ACTAAT GAGT 10757 10779 CCAATGCTAAAACTAAT 1956 GGGACGATTAGTTTTA 3725 CGTCCC GCAT 10777 10799 CCCAACAATTATATTAC 1957 GTGGTAGTAATATAAT 3726 TACCAC TGTT 10778 10800 CCAACAATTATATTACT 1958 AGTGGTAGTAATATAA 3727 ACCACT TTGT 10796 10818 CCACTGACATGACTTTC 1959 TTTTTGGAAAGTCATG 3728 CAAAAA TCAG 10812 10834 CCAAAAAACACATAATT 1960 GATTCAAATTATGTGT 3729 TGAATC TTTT 10842 10864 CCACCCACAGCCTAATT 1961 GCTAATAATTAGGCTG 3730 ATTAGC TGGG 10845 10867 CCCACAGCCTAATTATT 1962 GATGCTAATAATTAGG 3731 AGCATC CTGT 10846 10868 CCACAGCCTAATTATTA 1963 TGATGCTAATAATTAG 3732 GCATCA GCTG 10852 10874 CCTAATTATTAGCATCA 1964 GAGGGATGATGCTAAT 3733 TCCCTC AATT 10870 10892 CCCTCTACTATTTTTTAA 1965 TTTGGTTAAAAAATAG 3734 CCAAA TAGA 10871 10893 CCTCTACTATTTTTTAAC 1966 ATTTGGTTAAAAAATA 3735 CAAAT GTAG 10888 10910 CCAAATCAACAACAACC 1967 TAAATAGGTTGTTGTT 3736 TATTTA GATT 10903 10925 CCTATTTAGCTGTTCCC 1968 AGGTTGGGGAACAGCT 3737 CAACCT AAAT 10917 10939 CCCCAACCTTTTCCTCC 1969 GGGGTCGGAGGAAAA 3738 GACCCC GGTTG 10918 10940 CCCAACCTTTTCCTCCG 1970 GGGGGTCGGAGGAAA 3739 ACCCCC AGGTT 10919 10941 CCAACCTTTTCCTCCGA 1971 AGGGGGTCGGAGGAA 3740 CCCCCT AAGGT 10923 10945 CCTTTTCCTCCGACCCC 1972 TGTTAGGGGGTCGGAG 3741 CTAACA GAAA 10929 10951 CCTCCGACCCCCTAACA 1973 GGGGGTTGTTAGGGGG 3742 ACCCCC TCGG 10932 10954 CCGACCCCCTAACAACC 1974 GAGGGGGGTTGTTAGG 3743 CCCCTC GGGT 10936 10958 CCCCCTAACAACCCCCC 1975 TTAGGAGGGGGGTTGT 3744 TCCTAA TAGG 10937 10959 CCCCTAACAACCCCCCT 1976 ATTAGGAGGGGGGTTG 3745 CCTAAT TTAG 10938 10960 CCCTAACAACCCCCCTC 1977 TATTAGGAGGGGGGTT 3746 CTAATA GTTA 10939 10961 CCTAACAACCCCCCTCC 1978 GTATTAGGAGGGGGGT 3747 TAATAC TGTT 10947 10969 CCCCCCTCCTAATACTA 1979 GGTAGTTAGTATTAGG 3748 ACTACC AGGG 10948 10970 CCCCCTCCTAATACTAA 1980 AGGTAGTTAGTATTAG 3749 CTACCT GAGG 10949 10971 CCCCTCCTAATACTAAC 1981 CAGGTAGTTAGTATTA 3750 TACCTG GGAG 10950 10972 CCCTCCTAATACTAACT 1982 TCAGGTAGTTAGTATT 3751 ACCTGA AGGA 10951 10973 CCTCCTAATACTAACTA 1983 GTCAGGTAGTTAGTAT 3752 CCTGAC TAGG 10954 10976 CCTAATACTAACTACCT 1984 GGAGTCAGGTAGTTAG 3753 GACTCC TATT 10968 10990 CCTGACTCCTACCCCTC 1985 GATTGTGAGGGGTAGG 3754 ACAATC AGTC 10975 10997 CCTACCCCTCACAATCA 1986 TTGCCATGATTGTGAG 3755 TGGCAA GGGT 10979 11001 CCCCTCACAATCATGGC 1987 TGGCTTGCCATGATTG 3756 AAGCCA TGAG 10980 11002 CCCTCACAATCATGGCA 1988 TTGGCTTGCCATGATT 3757 AGCCAA GTGA 10981 11003 CCTCACAATCATGGCAA 1989 GTTGGCTTGCCATGAT 3758 GCCAAC TGTG 10999 11021 CCAACGCCACTTATCCA 1990 GTTCACTGGATAAGTG 3759 GTGAAC GCGT 11005 11027 CCACTTATCCAGTGAAC 1991 ATAGTGGTTCACTGGA 3760 CACTAT TAAG 11013 11035 CCAGTGAACCACTATCA 1992 TTTTCGTGATAGTGGT 3761 CGAAAA TCAC 11021 11043 CCACTATCACGAAAAAA 1993 TAGAGTTTTTTTCGTG 3762 ACTCTA ATAG 11044 11066 CCTCTCTATACTAATCT 1994 GTAGGGAGATTAGTAT 3763 CCCTAC AGAG 11061 11083 CCCTACAAATCTCCTTA 1995 TATAATTAAGGAGATT 3764 ATTATA TGTA 11062 11084 CCTACAAATCTCCTTAA 1996 TTATAATTAAGGAGAT 3765 TTATAA TTGT 11073 11095 CCTTAATTATAACATTC 1997 GGCTGTGAATGTTATA 3766 ACAGCC ATTA 11094 11116 CCACAGAACTAATCATA 1998 ATAAAATATGATTAGT 3767 TTTTAT TCTG 11130 11152 CCACACTTATCCCCACC 1999 AGCCAAGGTGGGGAT 3768 TTGGCT AAGTG 11140 11162 CCCCACCTTGGCTATCA 2000 GGGTGATGATAGCCAA 3769 TCACCC GGTG 11141 11163 CCCACCTTGGCTATCAT 2001 CGGGTGATGATAGCCA 3770 CACCCG AGGT 11142 11164 CCACCTTGGCTATCATC 2002 TCGGGTGATGATAGCC 3771 ACCCGA AAGG 11145 11167 CCTTGGCTATCATCACC 2003 TCATCGGGTGATGATA 3772 CGATGA GCCA 11160 11182 CCCGATGAGGCAACCA 2004 TTCTGGCTGGTTGCCT 3773 GCCAGAA CATC 11161 11183 CCGATGAGGCAACCAG 2005 GTTCTGGCTGGTTGCC 3774 CCAGAAC TCAT 11173 11195 CCAGCCAGAACGCCTGA 2006 CTGCGTTCAGGCGTTC 3775 ACGCAG TGGC 11177 11199 CCAGAACGCCTGAACGC 2007 GTGCCTGCGTTCAGGC 3776 AGGCAC GTTC 11185 11207 CCTGAACGCAGGCACAT 2008 GGAAGTATGTGCCTGC 3777 ACTTCC GTTC 11206 11228 CCTATTCTACACCCTAG 2009 AGCCTACTAGGGTGTA 3778 TAGGCT GAAT 11217 11239 CCCTAGTAGGCTCCCTT 2010 TAGGGGAAGGGAGCC 3779 CCCCTA TACTA 11218 11240 CCTAGTAGGCTCCCTTC 2011 GTAGGGGAAGGGAGC 3780 CCCTAC CTACT 11229 11251 CCCTTCCCCTACTCATC 2012 TAGTGCGATGAGTAGG 3781 GCACTA GGAA 11230 11252 CCTTCCCCTACTCATCG 2013 TTAGTGCGATGAGTAG 3782 CACTAA GGGA 11234 11256 CCCCTACTCATCGCACT 2014 TAAATTAGTGCGATGA 3783 AATTTA GTAG 11235 11257 CCCTACTCATCGCACTA 2015 GTAAATTAGTGCGATG 3784 ATTTAC AGTA 11236 11258 CCTACTCATCGCACTAA 2016 TGTAAATTAGTGCGAT 3785 TTTACA GAGT 11268 11290 CCCTAGGCTCACTAAAC 2017 TAGAATGTTTAGTGAG 3786 ATTCTA CCTA 11269 11291 CCTAGGCTCACTAAACA 2018 GTAGAATGTTTAGTGA 3787 TTCTAC GCCT 11307 11329 CCCAAGAACTATCAAAC 2019 TCAGGAGTTTGATAGT 3788 TCCTGA TCTT 11308 11330 CCAAGAACTATCAAACT 2020 CTCAGGAGTTTGATAG 3789 CCTGAG TTCT 11325 11347 CCTGAGCCAACAACTTA 2021 TCATATTAAGTTGTTG 3790 ATATGA GCTC 11331 11353 CCAACAACTTAATATGA 2022 AGCTAGTCATATTAAG 3791 CTAGCT TTGT 11381 11403 CCTCTTTACGGACTCCA 2023 CATAAGTGGAGTCCGT 3792 CTTATG AAAG 11395 11417 CCACTTATGACTCCCTA 2024 GGGCTTTAGGGAGTCA 3793 AAGCCC TAAG 11407 11429 CCCTAAAGCCCATGTCG 2025 GGGCTTCGACATGGGC 3794 AAGCCC TTTA 11408 11430 CCTAAAGCCCATGTCGA 2026 GGGGCTTCGACATGGG 3795 AGCCCC CTTT 11415 11437 CCCATGTCGAAGCCCCC 2027 AGCGATGGGGGCTTCG 3796 ATCGCT ACAT 11416 11438 CCATGTCGAAGCCCCCA 2028 CAGCGATGGGGGCTTC 3797 TCGCTG GACA 11427 11449 CCCCCATCGCTGGGTCA 2029 TACTATTGACCCAGCG 3798 ATAGTA ATGG 11428 11450 CCCCATCGCTGGGTCAA 2030 GTACTATTGACCCAGC 3799 TAGTAC GATG 11429 11451 CCCATCGCTGGGTCAAT 2031 AGTACTATTGACCCAG 3800 AGTACT CGAT 11430 11452 CCATCGCTGGGTCAATA 2032 AAGTACTATTGACCCA 3801 GTACTT GCGA 11454 11476 CCGCAGTACTCTTAAAA 2033 GCCTAGTTTTAAGAGT 3802 CTAGGC ACTG 11494 11516 CCTCACACTCATTCTCA 2034 GGGGGTTGAGAATGA 3803 ACCCCC GTGTG 11512 11534 CCCCCTGACAAAACACA 2035 AGGCTATGTGTTTTGT 3804 TAGCCT CAGG 11513 11535 CCCCTGACAAAACACAT 2036 TAGGCTATGTGTTTTG 3805 AGCCTA TCAG 11514 11536 CCCTGACAAAACACATA 2037 GTAGGCTATGTGTTTT 3806 GCCTAC GTCA 11515 11537 CCTGACAAAACACATAG 2038 GGTAGGCTATGTGTTT 3807 CCTACC TGTC 11532 11554 CCTACCCCTTCCTTGTA 2039 GGATAGTACAAGGAA 3808 CTATCC GGGGT 11536 11558 CCCCTTCCTTGTACTATC 2040 ATAGGGATAGTACAA 3809 CCTAT GGAAG 11537 11559 CCCTTCCTTGTACTATCC 2041 CATAGGGATAGTACAA 3810 CTATG GGAA 11538 11560 CCTTCCTTGTACTATCCC 2042 TCATAGGGATAGTACA 3811 TATGA AGGA 11542 11564 CCTTGTACTATCCCTAT 2043 TGCCTCATAGGGATAG 3812 GAGGCA TACA 11553 11575 CCCTATGAGGCATAATT 2044 TGTTATAATTATGCCT 3813 ATAACA CATA 11554 11576 CCTATGAGGCATAATTA 2045 TTGTTATAATTATGCC 3814 TAACAA TCAT 11580 11602 CCATCTGCCTACGACAA 2046 GTCTGTTTGTCGTAGG 3815 ACAGAC CAGA 11587 11609 CCTACGACAAACAGACC 2047 ATTTTAGGTCTGTTTGT 3816 TAAAAT CGT 11602 11624 CCTAAAATCGCTCATTG 2048 AGTATGCAATGAGCGA 3817 CATACT TTTT 11635 11657 CCACATAGCCCTCGTAG 2049 CTGTTACTACGAGGGC 3818 TAACAG TATG 11643 11665 CCCTCGTAGTAACAGCC 2050 GAGAATGGCTGTTACT 3819 ATTCTC ACGA 11644 11666 CCTCGTAGTAACAGCCA 2051 TGAGAATGGCTGTTAC 3820 TTCTCA TACG 11658 11680 CCATTCTCATCCAAACC 2052 TCAGGGGGTTTGGATG 3821 CCCTGA AGAA 11668 11690 CCAAACCCCCTGAAGCT 2053 CGGTGAAGCTTCAGGG 3822 TCACCG GGTT 11673 11695 CCCCCTGAAGCTTCACC 2054 TGCGCCGGTGAAGCTT 3823 GGCGCA CAGG 11674 11696 CCCCTGAAGCTTCACCG 2055 CTGCGCCGGTGAAGCT 3824 GCGCAG TCAG 11675 11697 CCCTGAAGCTTCACCGG 2056 ACTGCGCCGGTGAAGC 3825 CGCAGT TTCA 11676 11698 CCTGAAGCTTCACCGGC 2057 GACTGCGCCGGTGAAG 3826 GCAGTC CTTC 11688 11710 CCGGCGCAGTCATTCTC 2058 GATTATGAGAATGACT 3827 ATAATC GCGC 11712 11734 CCCACGGGCTTACATCC 2059 TAATGAGGATGTAAGC 3828 TCATTA CCGT 11713 11735 CCACGGGCTTACATCCT 2060 GTAATGAGGATGTAAG 3829 CATTAC CCCG 11727 11749 CCTCATTACTATTCTGC 2061 TGCTAGGCAGAATAGT 3830 CTAGCA AATG 11743 11765 CCTAGCAAACTCAAACT 2062 GTTCGTAGTTTGAGTT 3831 ACGAAC TGCT 11788 11810 CCTCTCTCAAGGACTTC 2063 GAGTTTGAAGTCCTTG 3832 AAACTC AGAG 11815 11837 CCCACTAATAGCTTTTT 2064 GTCATCAAAAAGCTAT 3833 GATGAC TAGT 11816 11838 CCACTAATAGCTTTTTG 2065 AGTCATCAAAAAGCTA 3834 ATGACT TTAG 11848 11870 CCTCGCTAACCTCGCCT 2066 GGGGTAAGGCGAGGT 3835 TACCCC TAGCG 11857 11879 CCTCGCCTTACCCCCCA 2067 TAATAGTGGGGGGTAA 3836 CTATTA GGCG 11862 11884 CCTTACCCCCCACTATT 2068 TAGGTTAATAGTGGGG 3837 AACCTA GGTA 11867 11889 CCCCCCACTATTAACCT 2069 CCCAGTAGGTTAATAG 3838 ACTGGG TGGG 11868 11890 CCCCCACTATTAACCTA 2070 TCCCAGTAGGTTAATA 3839 CTGGGA GTGG 11869 11891 CCCCACTATTAACCTAC 2071 CTCCCAGTAGGTTAAT 3840 TGGGAG AGTG 11870 11892 CCCACTATTAACCTACT 2072 TCTCCCAGTAGGTTAA 3841 GGGAGA TAGT 11871 11893 CCACTATTAACCTACTG 2073 TTCTCCCAGTAGGTTA 3842 GGAGAA ATAG 11881 11903 CCTACTGGGAGAACTCT 2074 GCACAGAGAGTTCTCC 3843 CTGTGC CAGT 11910 11932 CCACGTTCTCCTGATCA 2075 GATATTTGATCAGGAG 3844 AATATC AACG 11919 11941 CCTGATCAAATATCACT 2076 TAGGAGAGTGATATTT 3845 CTCCTA GATC 11938 11960 CCTACTTACAGGACTCA 2077 GTATGTTGAGTCCTGT 3846 ACATAC AAGT 11970 11992 CCCTATACTCCCTCTAC 2078 AAATATGTAGAGGGA 3847 ATATTT GTATA 11971 11993 CCTATACTCCCTCTACA 2079 TAAATATGTAGAGGGA 3848 TATTTA GTAT 11979 12001 CCCTCTACATATTTACC 2080 TGTTGTGGTAAATATG 3849 ACAACA TAGA 11980 12002 CCTCTACATATTTACCA 2081 GTGTTGTGGTAAATAT 3850 CAACAC GTAG 11994 12016 CCACAACACAATGGGG 2082 GAGTGAGCCCCATTGT 3851 CTCACTC GTTG 12018 12040 CCCACCACATTAACAAC 2083 TTTTATGTTGTTAATGT 3852 ATAAAA GGT 12019 12041 CCACCACATTAACAACA 2084 GTTTTATGTTGTTAAT 3853 TAAAAC GTGG 12022 12044 CCACATTAACAACATAA 2085 AGGGTTTTATGTTGTT 3854 AACCCT AATG 12041 12063 CCCTCATTCACACGAGA 2086 GTGTTTTCTCGTGTGA 3855 AAACAC ATGA 12042 12064 CCTCATTCACACGAGAA 2087 GGTGTTTTCTCGTGTG 3856 AACACC AATG 12063 12085 CCCTCATGTTCATACAC 2088 GGATAGGTGTATGAAC 3857 CTATCC ATGA 12064 12086 CCTCATGTTCATACACC 2089 GGGATAGGTGTATGAA 3858 TATCCC CATG 12079 12101 CCTATCCCCCATTCTCCT 2090 ATAGGAGGAGAATGG 3859 CCTAT GGGAT 12084 12106 CCCCCATTCTCCTCCTAT 2091 GAGGGATAGGAGGAG 3860 CCCTC AATGG 12085 12107 CCCCATTCTCCTCCTATC 2092 TGAGGGATAGGAGGA 3861 CCTCA GAATG 12086 12108 CCCATTCTCCTCCTATCC 2093 TTGAGGGATAGGAGG 3862 CTCAA AGAAT 12087 12109 CCATTCTCCTCCTATCCC 2094 GTTGAGGGATAGGAG 3863 TCAAC GAGAA 12094 12116 CCTCCTATCCCTCAACC 2095 TGTCGGGGTTGAGGGA 3864 CCGACA TAGG 12097 12119 CCTATCCCTCAACCCCG 2096 TGATGTCGGGGTTGAG 3865 ACATCA GGAT 12102 12124 CCCTCAACCCCGACATC 2097 GGTAATGATGTCGGGG 3866 ATTACC TTGA 12103 12125 CCTCAACCCCGACATCA 2098 CGGTAATGATGTCGGG 3867 TTACCG GTTG 12109 12131 CCCCGACATCATTACCG 2099 AAAACCCGGTAATGAT 3868 GGTTTT GTCG 12110 12132 CCCGACATCATTACCGG 2100 GAAAACCCGGTAATG 3869 GTTTTC ATGTC 12111 12133 CCGACATCATTACCGGG 2101 GGAAAACCCGGTAAT 3870 TTTTCC GATGT 12123 12145 CCGGGTTTTCCTCTTGT 2102 ATATTTACAAGAGGAA 3871 AAATAT AACC 12132 12154 CCTCTTGTAAATATAGT 2103 GGTTAAACTATATTTA 3872 TTAACC CAAG 12153 12175 CCAAAACATCAGATTGT 2104 AGATTCACAATCTGAT 3873 GAATCT GTTT 12194 12216 CCCCTTATTTACCGAGA 2105 GAGCTTTCTCGGTAAA 3874 AAGCTC TAAG 12195 12217 CCCTTATTTACCGAGAA 2106 TGAGCTTTCTCGGTAA 3875 AGCTCA ATAA 12196 12218 CCTTATTTACCGAGAAA 2107 GTGAGCTTTCTCGGTA 3876 GCTCAC AATA 12205 12227 CCGAGAAAGCTCACAA 2108 GCAGTTCTTGTGAGCT 3877 GAACTGC TTCT 12237 12259 CCCCCATGTCTAACAAC 2109 AGCCATGTTGTTAGAC 3878 ATGGCT ATGG 12238 12260 CCCCATGTCTAACAACA 2110 AAGCCATGTTGTTAGA 3879 TGGCTT CATG 12239 12261 CCCATGTCTAACAACAT 2111 AAAGCCATGTTGTTAG 3880 GGCTTT ACAT 12240 12262 CCATGTCTAACAACATG 2112 GAAAGCCATGTTGTTA 3881 GCTTTC GACA 12288 12310 CCATTGGTCTTAGGCCC 2113 TTTTTGGGGCCTAAGA 3882 CAAAAA CCAA 12302 12324 CCCCAAAAATTTTGGTG 2114 GAGTTGCACCAAAATT 3883 CAACTC TTTG 12303 12325 CCCAAAAATTTTGGTGC 2115 GGAGTTGCACCAAAAT 3884 AACTCC TTTT 12304 12326 CCAAAAATTTTGGTGCA 2116 TGGAGTTGCACCAAAA 3885 ACTCCA TTTT 12324 12346 CCAAATAAAAGTAATA 2117 GCATGGTTATTACTTT 3886 ACCATGC TATT 12341 12363 CCATGCACACTACTATA 2118 GGTGGTTATAGTAGTG 3887 ACCACC TGCA 12359 12381 CCACCCTAACCCTGACT 2119 TAGGGAAGTCAGGGTT 3888 TCCCTA AGGG 12362 12384 CCCTAACCCTGACTTCC 2120 AATTAGGGAAGTCAG 3889 CTAATT GGTTA 12363 12385 CCTAACCCTGACTTCCC 2121 GAATTAGGGAAGTCA 3890 TAATTC GGGTT 12368 12390 CCCTGACTTCCCTAATT 2122 GGGGGGAATTAGGGA 3891 CCCCCC AGTCA 12369 12391 CCTGACTTCCCTAATTC 2123 TGGGGGGAATTAGGG 3892 CCCCCA AAGTC 12377 12399 CCCTAATTCCCCCCATC 2124 GGTAAGGATGGGGGG 3893 CTTACC AATTA 12378 12400 CCTAATTCCCCCCATCC 2125 TGGTAAGGATGGGGG 3894 TTACCA GAATT 12385 12407 CCCCCCATCCTTACCAC 2126 ACGAGGGTGGTAAGG 3895 CCTCGT ATGGG 12386 12408 CCCCCATCCTTACCACC 2127 AACGAGGGTGGTAAG 3896 CTCGTT GATGG 12387 12409 CCCCATCCTTACCACCC 2128 TAACGAGGGTGGTAA 3897 TCGTTA GGATG 12388 12410 CCCATCCTTACCACCCT 2129 TTAACGAGGGTGGTAA 3898 CGTTAA GGAT 12389 12411 CCATCCTTACCACCCTC 2130 GTTAACGAGGGTGGTA 3899 GTTAAC AGGA 12393 12415 CCTTACCACCCTCGTTA 2131 TAGGGTTAACGAGGGT 3900 ACCCTA GGTA 12398 12420 CCACCCTCGTTAACCCT 2132 TTTGTTAGGGTTAACG 3901 AACAAA AGGG 12401 12423 CCCTCGTTAACCCTAAC 2133 TTTTTTGTTAGGGTTA 3902 AAAAAA ACGA 12402 12424 CCTCGTTAACCCTAACA 2134 TTTTTTTGTTAGGGTTA 3903 AAAAAA ACG 12411 12433 CCCTAACAAAAAAAACT 2135 GGTATGAGTTTTTTTT 3904 CATACC GTTA 12412 12434 CCTAACAAAAAAAACTC 2136 GGGTATGAGTTTTTTT 3905 ATACCC TGTT 12432 12454 CCCCCATTATGTAAAAT 2137 CAATGGATTTTACATA 3906 CCATTG ATGG 12433 12455 CCCCATTATGTAAAATC 2138 ACAATGGATTTTACAT 3907 CATTGT AATG 12434 12456 CCCATTATGTAAAATCC 2139 GACAATGGATTTTACA 3908 ATTGTC TAAT 12435 12457 CCATTATGTAAAATCCA 2140 CGACAATGGATTTTAC 3909 TTGTCG ATAA 12449 12471 CCATTGTCGCATCCACC 2141 AATAAAGGTGGATGC 3910 TTTATT GACAA 12461 12483 CCACCTTTATTATCAGT 2142 GAAGAGACTGATAAT 3911 CTCTTC AAAGG 12464 12486 CCTTTATTATCAGTCTCT 2143 GGGGAAGAGACTGAT 3912 TCCCC AATAA 12483 12505 CCCCACAACAATATTCA 2144 GGCACATGAATATTGT 3913 TGTGCC TGTG 12484 12506 CCCACAACAATATTCAT 2145 AGGCACATGAATATTG 3914 GTGCCT TTGT 12485 12507 CCACAACAATATTCATG 2146 TAGGCACATGAATATT 3915 TGCCTA GTTG 12504 12526 CCTAGACCAAGAAGTTA 2147 AGATAATAACTTCTTG 3916 TTATCT GTCT 12510 12532 CCAAGAAGTTATTATCT 2148 AGTTCGAGATAATAAC 3917 CGAACT TTCT 12542 12564 CCACAACCCAAACAACC 2149 GAGCTGGGTTGTTTGG 3918 CAGCTC GTTG 12548 12570 CCCAAACAACCCAGCTC 2150 TAGGGAGAGCTGGGTT 3919 TCCCTA GTTT 12549 12571 CCAAACAACCCAGCTCT 2151 TTAGGGAGAGCTGGGT 3920 CCCTAA TGTT 12557 12579 CCCAGCTCTCCCTAAGC 2152 TTTGAAGCTTAGGGAG 3921 TTCAAA AGCT 12558 12580 CCAGCTCTCCCTAAGCT 2153 GTTTGAAGCTTAGGGA 3922 TCAAAC GAGC 12566 12588 CCCTAAGCTTCAAACTA 2154 GTAGTCTAGTTTGAAG 3923 GACTAC CTTA 12567 12589 CCTAAGCTTCAAACTAG 2155 AGTAGTCTAGTTTGAA 3924 ACTACT GCTT 12593 12615 CCATAATATTCATCCCT 2156 TGCTACAGGGATGAAT 3925 GTAGCA ATTA 12606 12628 CCCTGTAGCATTGTTCG 2157 ATGTAACGAACAATGC 3926 TTACAT TACA 12607 12629 CCTGTAGCATTGTTCGT 2158 CATGTAACGAACAATG 3927 TACATG CTAC 12632 12654 CCATCATAGAATTCTCA 2159 TCACAGTGAGAATTCT 3928 CTGTGA ATGA 12669 12691 CCCAAACATTAATCAGT 2160 TGAAGAACTGATTAAT 3929 TCTTCA GTTT 12670 12692 CCAAACATTAATCAGTT 2161 TTGAAGAACTGATTAA 3930 CTTCAA TGTT 12708 12730 CCTAATTACCATACTAA 2162 CTAAGATTAGTATGGT 3931 TCTTAG AATT 12716 12738 CCATACTAATCTTAGTT 2163 AGCGGTAACTAAGATT 3932 ACCGCT AGTA 12734 12756 CCGCTAACAACCTATTC 2164 CAGTTGGAATAGGTTG 3933 CAACTG TTAG 12744 12766 CCTATTCCAACTGTTCA 2165 AGCCGATGAACAGTTG 3934 TCGGCT GAAT 12750 12772 CCAACTGTTCATCGGCT 2166 CCTCTCAGCCGATGAA 3935 GAGAGG CAGT 12788 12810 CCTTCTTGCTCATCAGTT 2167 TCATCAACTGATGAGC 3936 GATGA AAGA 12815 12837 CCCGAGCAGATGCCAAC 2168 TGCTGTGTTGGCATCT 3937 ACAGCA GCTC 12816 12838 CCGAGCAGATGCCAAC 2169 CTGCTGTGTTGGCATC 3938 ACAGCAG TGCT 12827 12849 CCAACACAGCAGCCATT 2170 TGCTTGAATGGCTGCT 3939 CAAGCA GTGT 12839 12861 CCATTCAAGCAATCCTA 2171 GTTGTATAGGATTGCT 3940 TACAAC TGAA 12852 12874 CCTATACAACCGTATCG 2172 TATCGCCGATACGGTT 3941 GCGATA GTAT 12861 12883 CCGTATCGGCGATATCG 2173 TGAAACCGATATCGCC 3942 GTTTCA GATA 12885 12907 CCTCGCCTTAGCATGAT 2174 GGATAAATCATGCTAA 3943 TTATCC GGCG 12890 12912 CCTTAGCATGATTTATC 2175 GTGTAGGATAAATCAT 3944 CTACAC GCTA 12906 12928 CCTACACTCCAACTCAT 2176 GGTCTCATGAGTTGGA 3945 GAGACC GTGT 12914 12936 CCAACTCATGAGACCCA 2177 TTGTTGTGGGTCTCAT 3946 CAACAA GAGT 12927 12949 CCCACAACAAATAGCCC 2178 TTAGAAGGGCTATTTG 3947 TTCTAA TTGT 12928 12950 CCACAACAAATAGCCCT 2179 TTTAGAAGGGCTATTT 3948 TCTAAA GTTG 12941 12963 CCCTTCTAAACGCTAAT 2180 GCTTGGATTAGCGTTT 3949 CCAAGC AGAA 12942 12964 CCTTCTAAACGCTAATC 2181 GGCTTGGATTAGCGTT 3950 CAAGCC TAGA 12958 12980 CCAAGCCTCACCCCACT 2182 CCTAGTAGTGGGGTGA 3951 ACTAGG GGCT 12963 12985 CCTCACCCCACTACTAG 2183 GGAGGCCTAGTAGTGG 3952 GCCTCC GGTG 12968 12990 CCCCACTACTAGGCCTC 2184 TAGGAGGAGGCCTAGT 3953 CTCCTA AGTG 12969 12991 CCCACTACTAGGCCTCC 2185 CTAGGAGGAGGCCTA 3954 TCCTAG GTAGT 12970 12992 CCACTACTAGGCCTCCT 2186 GCTAGGAGGAGGCCT 3955 CCTAGC AGTAG 12981 13003 CCTCCTCCTAGCAGCAG 2187 TGCCTGCTGCTGCTAG 3956 CAGGCA GAGG 12984 13006 CCTCCTAGCAGCAGCAG 2188 ATTTGCCTGCTGCTGC 3957 GCAAAT TAGG 12987 13009 CCTAGCAGCAGCAGGC 2189 CTGATTTGCCTGCTGC 3958 AAATCAG TGCT 13010 13032 CCCAATTAGGTCTCCAC 2190 TCAGGGGTGGAGACCT 3959 CCCTGA AATT 13011 13033 CCAATTAGGTCTCCACC 2191 GTCAGGGGTGGAGAC 3960 CCTGAC CTAAT 13023 13045 CCACCCCTGACTCCCCT 2192 TGGCTGAGGGGAGTCA 3961 CAGCCA GGGG 13026 13048 CCCCTGACTCCCCTCAG 2193 CTATGGCTGAGGGGAG 3962 CCATAG TCAG 13027 13049 CCCTGACTCCCCTCAGC 2194 TCTATGGCTGAGGGGA 3963 CATAGA GTCA 13028 13050 CCTGACTCCCCTCAGCC 2195 TTCTATGGCTGAGGGG 3964 ATAGAA AGTC 13035 13057 CCCCTCAGCCATAGAAG 2196 TGGGGCCTTCTATGGC 3965 GCCCCA TGAG 13036 13058 CCCTCAGCCATAGAAGG 2197 GTGGGGCCTTCTATGG 3966 CCCCAC CTGA 13037 13059 CCTCAGCCATAGAAGGC 2198 GGTGGGGCCTTCTATG 3967 CCCACC GCTG 13043 13065 CCATAGAAGGCCCCACC 2199 GACTGGGGTGGGGCCT 3968 CCAGTC TCTA 13053 13075 CCCCACCCCAGTCTCAG 2200 GTAGGGCTGAGACTGG 3969 CCCTAC GGTG 13054 13076 CCCACCCCAGTCTCAGC 2201 AGTAGGGCTGAGACTG 3970 CCTACT GGGT 13055 13077 CCACCCCAGTCTCAGCC 2202 GAGTAGGGCTGAGACT 3971 CTACTC GGGG 13058 13080 CCCCAGTCTCAGCCCTA 2203 GTGGAGTAGGGCTGA 3972 CTCCAC GACTG 13059 13081 CCCAGTCTCAGCCCTAC 2204 AGTGGAGTAGGGCTG 3973 TCCACT AGACT 13060 13082 CCAGTCTCAGCCCTACT 2205 GAGTGGAGTAGGGCT 3974 CCACTC GAGAC 13070 13092 CCCTACTCCACTCAAGC 2206 TATAGTGCTTGAGTGG 3975 ACTATA AGTA 13071 13093 CCTACTCCACTCAAGCA 2207 CTATAGTGCTTGAGTG 3976 CTATAG GAGT 13077 13099 CCACTCAAGCACTATAG 2208 CTACAACTATAGTGCT 3977 TTGTAG TGAG 13119 13141 CCGCTTCCACCCCCTAG 2209 TTTCTGCTAGGGGGTG 3978 CAGAAA GAAG 13125 13147 CCACCCCCTAGCAGAAA 2210 GGCTATTTTCTGCTAG 3979 ATAGCC GGGG 13128 13150 CCCCCTAGCAGAAAATA 2211 GTGGGCTATTTTCTGC 3980 GCCCAC TAGG 13129 13151 CCCCTAGCAGAAAATAG 2212 AGTGGGCTATTTTCTG 3981 CCCACT CTAG 13130 13152 CCCTAGCAGAAAATAGC 2213 TAGTGGGCTATTTTCT 3982 CCACTA GCTA 13131 13153 CCTAGCAGAAAATAGCC 2214 TTAGTGGGCTATTTTC 3983 CACTAA TGCT 13146 13168 CCCACTAATCCAAACTC 2215 GTGTTAGAGTTTGGAT 3984 TAACAC TAGT 13147 13169 CCACTAATCCAAACTCT 2216 AGTGTTAGAGTTTGGA 3985 AACACT TTAG 13155 13177 CCAAACTCTAACACTAT 2217 CTAAGCATAGTGTTAG 3986 GCTTAG AGTT 13187 13209 CCACTCTGTTCGCAGCA 2218 GCAGACTGCTGCGAAC 3987 GTCTGC AGAG 13211 13233 CCCTTACACAAAATGAC 2219 TTTGATGTCATTTTGTG 3988 ATCAAA TAA 13212 13234 CCTTACACAAAATGACA 2220 TTTTGATGTCATTTTGT 3989 TCAAAA GTA 13244 13266 CCTTCTCCACTTCAAGT 2221 TAGTTGACTTGAAGTG 3990 CAACTA GAGA 13250 13272 CCACTTCAAGTCAACTA 2222 GAGTCCTAGTTGACTT 3991 GGACTC GAAG 13296 13318 CCAACCACACCTAGCAT 2223 GCAGGAATGCTAGGTG 3992 TCCTGC TGGT 13300 13322 CCACACCTAGCATTCCT 2224 ATGTGCAGGAATGCTA 3993 GCACAT GGTG 13305 13327 CCTAGCATTCCTGCACA 2225 TACAGATGTGCAGGAA 3994 TCTGTA TGCT 13314 13336 CCTGCACATCTGTACCC 2226 AGGCGTGGGTACAGAT 3995 ACGCCT GTGC 13328 13350 CCCACGCCTTCTTCAAA 2227 TATGGCTTTGAAGAAG 3996 GCCATA GCGT 13329 13351 CCACGCCTTCTTCAAAG 2228 GTATGGCTTTGAAGAA 3997 CCATAC GGCG 13334 13356 CCTTCTTCAAAGCCATA 2229 AAATAGTATGGCTTTG 3998 CTATTT AAGA 13346 13368 CCATACTATTTATGTGC 2230 CCCGGAGCACATAAAT 3999 TCCGGG AGTA 13364 13386 CCGGGTCCATCATCCAC 2231 AAGGTTGTGGATGATG 4000 AACCTT GACC 13370 13392 CCATCATCCACAACCTT 2232 ATTGTTAAGGTTGTGG 4001 AACAAT ATGA 13377 13399 CCACAACCTTAACAATG 2233 CTTGTTCATTGTTAAG 4002 AACAAG GTTG 13383 13405 CCTTAACAATGAACAAG 2234 GAATATCTTGTTCATT 4003 ATATTC GTTA 13430 13452 CCATACCTCTCACTTCA 2235 GGAGGTTGAAGTGAG 4004 ACCTCC AGGTA 13435 13457 CCTCTCACTTCAACCTC 2236 GTGAGGGAGGTTGAA 4005 CCTCAC GTGAG 13448 13470 CCTCCCTCACCATTGGC 2237 TAGGCTGCCAATGGTG 4006 AGCCTA AGGG 13451 13473 CCCTCACCATTGGCAGC 2238 TGCTAGGCTGCCAATG 4007 CTAGCA GTGA 13452 13474 CCTCACCATTGGCAGCC 2239 ATGCTAGGCTGCCAAT 4008 TAGCAT GGTG 13457 13479 CCATTGGCAGCCTAGCA 2240 TGCTAATGCTAGGCTG 4009 TTAGCA CCAA 13467 13489 CCTAGCATTAGCAGGAA 2241 AAGGTATTCCTGCTAA 4010 TACCTT TGCT 13486 13508 CCTTTCCTCACAGGTTT 2242 GAGTAGAAACCTGTGA 4011 CTACTC GGAA 13491 13513 CCTCACAGGTTTCTACT 2243 CTTTGGAGTAGAAACC 4012 CCAAAG TGTG 13508 13530 CCAAAGACCACATCATC 2244 GGTTTCGATGATGTGG 4013 GAAACC TCTT 13515 13537 CCACATCATCGAAACCG 2245 TGTTTGCGGTTTCGAT 4014 CAAACA GATG 13529 13551 CCGCAAACATATCATAC 2246 GTTTGTGTATGATATG 4015 ACAAAC TTTG 13553 13575 CCTGAGCCCTATCTATT 2247 GAGAGTAATAGATAG 4016 ACTCTC GGCTC 13559 13581 CCCTATCTATTACTCTC 2248 AGCGATGAGAGTAAT 4017 ATCGCT AGATA 13560 13582 CCTATCTATTACTCTCAT 2249 TAGCGATGAGAGTAAT 4018 CGCTA AGAT 13583 13605 CCTCCCTGACAAGCGCC 2250 GCTATAGGCGCTTGTC 4019 TATAGC AGGG 13586 13608 CCCTGACAAGCGCCTAT 2251 AGTGCTATAGGCGCTT 4020 AGCACT GTCA 13587 13609 CCTGACAAGCGCCTATA 2252 GAGTGCTATAGGCGCT 4021 GCACTC TGTC 13598 13620 CCTATAGCACTCGAATA 2253 AAGAATTATTCGAGTG 4022 ATTCTT CTAT 13625 13647 CCCTAACAGGTCAACCT 2254 GAAGCGAGGTTGACCT 4023 CGCTTC GTTA 13626 13648 CCTAACAGGTCAACCTC 2255 GGAAGCGAGGTTGAC 4024 GCTTCC CTGTT 13639 13661 CCTCGCTTCCCCACCCT 2256 TTAGTAAGGGTGGGGA 4025 TACTAA AGCG 13647 13669 CCCCACCCTTACTAACA 2257 CGTTAATGTTAGTAAG 4026 TTAACG GGTG 13648 13670 CCCACCCTTACTAACAT 2258 TCGTTAATGTTAGTAA 4027 TAACGA GGGT 13649 13671 CCACCCTTACTAACATT 2259 TTCGTTAATGTTAGTA 4028 AACGAA AGGG 13652 13674 CCCTTACTAACATTAAC 2260 ATTTTCGTTAATGTTA 4029 GAAAAT GTAA 13653 13675 CCTTACTAACATTAACG 2261 TATTTTCGTTAATGTTA 4030 AAAATA GTA 13677 13699 CCCCACCCTACTAAACC 2262 TAATGGGGTTTAGTAG 4031 CCATTA GGTG 13678 13700 CCCACCCTACTAAACCC 2263 TTAATGGGGTTTAGTA 4032 CATTAA GGGT 13679 13701 CCACCCTACTAAACCCC 2264 TTTAATGGGGTTTAGT 4033 ATTAAA AGGG 13682 13704 CCCTACTAAACCCCATT 2265 GCGTTTAATGGGGTTT 4034 AAACGC AGTA 13683 13705 CCTACTAAACCCCATTA 2266 GGCGTTTAATGGGGTT 4035 AACGCC TAGT 13692 13714 CCCCATTAAACGCCTGG 2267 CGGCTGCCAGGCGTTT 4036 CAGCCG AATG 13693 13715 CCCATTAAACGCCTGGC 2268 CCGGCTGCCAGGCGTT 4037 AGCCGG TAAT 13694 13716 CCATTAAACGCCTGGCA 2269 TCCGGCTGCCAGGCGT 4038 GCCGGA TTAA 13704 13726 CCTGGCAGCCGGAAGCC 2270 CGAATAGGCTTCCGGC 4039 TATTCG TGCC 13712 13734 CCGGAAGCCTATTCGCA 2271 AAATCCTGCGAATAGG 4040 GGATTT CTTC 13719 13741 CCTATTCGCAGGATTTC 2272 TAATGAGAAATCCTGC 4041 TCATTA GAAT 13754 13776 CCCCCGCATCCCCCTTC 2273 TGTTTGGAAGGGGGAT 4042 CAAACA GCGG 13755 13777 CCCCGCATCCCCCTTCC 2274 TTGTTTGGAAGGGGGA 4043 AAACAA TGCG 13756 13778 CCCGCATCCCCCTTCCA 2275 GTTGTTTGGAAGGGGG 4044 AACAAC ATGC 13757 13779 CCGCATCCCCCTTCCAA 2276 TGTTGTTTGGAAGGGG 4045 ACAACA GATG 13763 13785 CCCCCTTCCAAACAACA 2277 GGGGATTGTTGTTTGG 4046 ATCCCC AAGG 13764 13786 CCCCTTCCAAACAACAA 2278 GGGGGATTGTTGTTTG 4047 TCCCCC GAAG 13765 13787 CCCTTCCAAACAACAAT 2279 AGGGGGATTGTTGTTT 4048 CCCCCT GGAA 13766 13788 CCTTCCAAACAACAATC 2280 GAGGGGGATTGTTGTT 4049 CCCCTC TGGA 13770 13792 CCAAACAACAATCCCCC 2281 GGTAGAGGGGGATTGT 4050 TCTACC TGTT 13782 13804 CCCCCTCTACCTAAAAC 2282 CTGTGAGTTTTAGGTA 4051 TCACAG GAGG 13783 13805 CCCCTCTACCTAAAACT 2283 GCTGTGAGTTTTAGGT 4052 CACAGC AGAG 13784 13806 CCCTCTACCTAAAACTC 2284 GGCTGTGAGTTTTAGG 4053 ACAGCC TAGA 13785 13807 CCTCTACCTAAAACTCA 2285 GGGCTGTGAGTTTTAG 4054 CAGCCC GTAG 13791 13813 CCTAAAACTCACAGCCC 2286 CAGCGAGGGCTGTGA 4055 TCGCTG GTTTT 13805 13827 CCCTCGCTGTCACTTTC 2287 TCCTAGGAAAGTGACA 4056 CTAGGA GCGA 13806 13828 CCTCGCTGTCACTTTCCT 2288 GTCCTAGGAAAGTGAC 4057 AGGAC AGCG 13821 13843 CCTAGGACTTCTAACAG 2289 CTAGGGCTGTTAGAAG 4058 CCCTAG TCCT 13838 13860 CCCTAGACCTCAACTAC 2290 GGTTAGGTAGTTGAGG 4059 CTAACC TCTA 13839 13861 CCTAGACCTCAACTACC 2291 TGGTTAGGTAGTTGAG 4060 TAACCA GTCT 13845 13867 CCTCAACTACCTAACCA 2292 GTTTGTTGGTTAGGTA 4061 ACAAAC GTTG 13854 13876 CCTAACCAACAAACTTA 2293 TTATTTTAAGTTTGTTG 4062 AAATAA GTT 13859 13881 CCAACAAACTTAAAATA 2294 GGATTTTATTTTAAGT 4063 AAATCC TTGT 13880 13902 CCCCACTATGCACATTT 2295 GAAATAAAATGTGCAT 4064 TATTTC AGTG 13881 13903 CCCACTATGCACATTTT 2296 AGAAATAAAATGTGC 4065 ATTTCT ATAGT 13882 13904 CCACTATGCACATTTTA 2297 GAGAAATAAAATGTG 4066 TTTCTC CATAG 13904 13926 CCAACATACTCGGATTC 2298 AGGGTAGAATCCGAGT 4067 TACCCT ATGT 13923 13945 CCCTAGCATCACACACC 2299 TTGTGCGGTGTGTGAT 4068 GCACAA GCTA 13924 13946 CCTAGCATCACACACCG 2300 ATTGTGCGGTGTGTGA 4069 CACAAT TGCT 13938 13960 CCGCACAATCCCCTATC 2301 GGCCTAGATAGGGGAT 4070 TAGGCC TGTG 13947 13969 CCCCTATCTAGGCCTTC 2302 TCGTAAGAAGGCCTAG 4071 TTACGA ATAG 13948 13970 CCCTATCTAGGCCTTCT 2303 CTCGTAAGAAGGCCTA 4072 TACGAG GATA 13949 13971 CCTATCTAGGCCTTCTT 2304 GCTCGTAAGAAGGCCT 4073 ACGAGC AGAT 13959 13981 CCTTCTTACGAGCCAAA 2305 GCAGGTTTTGGCTCGT 4074 ACCTGC AAGA 13971 13993 CCAAAACCTGCCCCTAC 2306 GGAGGAGTAGGGGCA 4075 TCCTCC GGTTT 13977 13999 CCTGCCCCTACTCCTCC 2307 GGTCTAGGAGGAGTA 4076 TAGACC GGGGC 13981 14003 CCCCTACTCCTCCTAGA 2308 GTTAGGTCTAGGAGGA 4077 CCTAAC GTAG 13982 14004 CCCTACTCCTCCTAGAC 2309 GGTTAGGTCTAGGAGG 4078 CTAACC AGTA 13983 14005 CCTACTCCTCCTAGACC 2310 AGGTTAGGTCTAGGAG 4079 TAACCT GAGT 13989 14011 CCTCCTAGACCTAACCT 2311 CTAGTCAGGTTAGGTC 4080 GACTAG TAGG 13992 14014 CCTAGACCTAACCTGAC 2312 TTTCTAGTCAGGTTAG 4081 TAGAAA GTCT 13998 14020 CCTAACCTGACTAGAAA 2313 ATAGCTTTTCTAGTCA 4082 AGCTAT GGTT 14003 14025 CCTGACTAGAAAAGCTA 2314 AGGTAATAGCTTTTCT 4083 TTACCT AGTC 14023 14045 CCTAAAACAATTTCACA 2315 TGGTGCTGTGAAATTG 4084 GCACCA TTTT 14043 14065 CCAAATCTCCACCTCCA 2316 TGATGATGGAGGTGGA 4085 TCATCA GATT 14051 14073 CCACCTCCATCATCACC 2317 GGTTGAGGTGATGATG 4086 TCAACC GAGG 14054 14076 CCTCCATCATCACCTCA 2318 TTGGGTTGAGGTGATG 4087 ACCCAA ATGG 14057 14079 CCATCATCACCTCAACC 2319 TTTTTGGGTTGAGGTG 4088 CAAAAA ATGA 14066 14088 CCTCAACCCAAAAAGGC 2320 AATTATGCCTTTTTGG 4089 ATAATT GTTG 14072 14094 CCCAAAAAGGCATAATT 2321 AAGTTTAATTATGCCT 4090 AAACTT TTTT 14073 14095 CCAAAAAGGCATAATTA 2322 AAAGTTTAATTATGCC 4091 AACTTT TTTT 14100 14122 CCTCTCTTTCTTCTTCCC 2323 TGAGTGGGAAGAAGA 4092 ACTCA AAGAG 14115 14137 CCCACTCATCCTAACCC 2324 GGAGTAGGGTTAGGAT 4093 TACTCC GAGT 14116 14138 CCACTCATCCTAACCCT 2325 AGGAGTAGGGTTAGG 4094 ACTCCT ATGAG 14124 14146 CCTAACCCTACTCCTAA 2326 ATGTGATTAGGAGTAG 4095 TCACAT GGTT 14129 14151 CCCTACTCCTAATCACA 2327 AGGTTATGTGATTAGG 4096 TAACCT AGTA 14130 14152 CCTACTCCTAATCACAT 2328 TAGGTTATGTGATTAG 4097 AACCTA GAGT 14136 14158 CCTAATCACATAACCTA 2329 GGGGAATAGGTTATGT 4098 TTCCCC GATT 14149 14171 CCTATTCCCCCGAGCAA 2330 TTGAGATTGCTCGGGG 4099 TCTCAA GAAT 14155 14177 CCCCCGAGCAATCTCAA 2331 TTGTAATTGAGATTGC 4100 TTACAA TCGG 14156 14178 CCCCGAGCAATCTCAAT 2332 ATTGTAATTGAGATTG 4101 TACAAT CTCG 14157 14179 CCCGAGCAATCTCAATT 2333 TATTGTAATTGAGATT 4102 ACAATA GCTC 14158 14180 CCGAGCAATCTCAATTA 2334 ATATTGTAATTGAGAT 4103 CAATAT TGCT 14186 14208 CCAACAAACAATGTTCA 2335 ACTGGTTGAACATTGT 4104 ACCAGT TTGT 14204 14226 CCAGTAACTACTACTAA 2336 CGTTGATTAGTAGTAG 4105 TCAACG TTAC 14227 14249 CCCATAATCATACAAAG 2337 CGGGGGCTTTGTATGA 4106 CCCCCG TTAT 14228 14250 CCATAATCATACAAAGC 2338 GCGGGGGCTTTGTATG 4107 CCCCGC ATTA 14244 14266 CCCCCGCACCAATAGGA 2339 GGAGGATCCTATTGGT 4108 TCCTCC GCGG 14245 14267 CCCCGCACCAATAGGAT 2340 GGGAGGATCCTATTGG 4109 CCTCCC TGCG 14246 14268 CCCGCACCAATAGGATC 2341 CGGGAGGATCCTATTG 4110 CTCCCG GTGC 14247 14269 CCGCACCAATAGGATCC 2342 TCGGGAGGATCCTATT 4111 TCCCGA GGTG 14252 14274 CCAATAGGATCCTCCCG 2343 TTGATTCGGGAGGATC 4112 AATCAA CTAT 14262 14284 CCTCCCGAATCAACCCT 2344 GGGGTCAGGGTTGATT 4113 GACCCC CGGG 14265 14287 CCCGAATCAACCCTGAC 2345 AGAGGGGTCAGGGTT 4114 CCCTCT GATTC 14266 14288 CCGAATCAACCCTGACC 2346 GAGAGGGGTCAGGGT 4115 CCTCTC TGATT 14275 14297 CCCTGACCCCTCTCCTT 2347 TTTATGAAGGAGAGGG 4116 CATAAA GTCA 14276 14298 CCTGACCCCTCTCCTTC 2348 ATTTATGAAGGAGAGG 4117 ATAAAT GGTC 14281 14303 CCCCTCTCCTTCATAAA 2349 GAATAATTTATGAAGG 4118 TTATTC AGAG 14282 14304 CCCTCTCCTTCATAAAT 2350 TGAATAATTTATGAAG 4119 TATTCA GAGA 14283 14305 CCTCTCCTTCATAAATT 2351 CTGAATAATTTATGAA 4120 ATTCAG GGAG 14288 14310 CCTTCATAAATTATTCA 2352 GGAAGCTGAATAATTT 4121 GCTTCC ATGA 14309 14331 CCTACACTATTAAAGTT 2353 GTGGTAAACTTTAATA 4122 TACCAC GTGT 14328 14350 CCACAACCACCACCCCA 2354 GTATGATGGGGTGGTG 4123 TCATAC GTTG 14334 14356 CCACCACCCCATCATAC 2355 GAAAGAGTATGATGG 4124 TCTTTC GGTGG 14337 14359 CCACCCCATCATACTCT 2356 GGTGAAAGAGTATGAT 4125 TTCACC GGGG 14340 14362 CCCCATCATACTCTTTC 2357 GTGGGTGAAAGAGTAT 4126 ACCCAC GATG 14341 14363 CCCATCATACTCTTTCA 2358 TGTGGGTGAAAGAGTA 4127 CCCACA TGAT 14342 14364 CCATCATACTCTTTCAC 2359 CTGTGGGTGAAAGAGT 4128 CCACAG ATGA 14358 14380 CCCACAGCACCAATCCT 2360 GGAGGTAGGATTGGTG 4129 ACCTCC CTGT 14359 14381 CCACAGCACCAATCCTA 2361 TGGAGGTAGGATTGGT 4130 CCTCCA GCTG 14367 14389 CCAATCCTACCTCCATC 2362 GTTAGCGATGGAGGTA 4131 GCTAAC GGAT 14372 14394 CCTACCTCCATCGCTAA 2363 GTGGGGTTAGCGATGG 4132 CCCCAC AGGT 14376 14398 CCTCCATCGCTAACCCC 2364 TTTAGTGGGGTTAGCG 4133 ACTAAA ATGG 14379 14401 CCATCGCTAACCCCACT 2365 TGTTTTAGTGGGGTTA 4134 AAAACA GCGA 14389 14411 CCCCACTAAAACACTCA 2366 TCTTGGTGAGTGTTTT 4135 CCAAGA AGTG 14390 14412 CCCACTAAAACACTCAC 2367 GTCTTGGTGAGTGTTT 4136 CAAGAC TAGT 14391 14413 CCACTAAAACACTCACC 2368 GGTCTTGGTGAGTGTT 4137 AAGACC TTAG 14406 14428 CCAAGACCTCAACCCCT 2369 GGGGTCAGGGGTTGA 4138 GACCCC GGTCT 14412 14434 CCTCAACCCCTGACCCC 2370 GGCATGGGGGTCAGG 4139 CATGCC GGTTG 14418 14440 CCCCTGACCCCCATGCC 2371 TCCTGAGGCATGGGGG 4140 TCAGGA TCAG 14419 14441 CCCTGACCCCCATGCCT 2372 ATCCTGAGGCATGGGG 4141 CAGGAT GTCA 14420 14442 CCTGACCCCCATGCCTC 2373 TATCCTGAGGCATGGG 4142 AGGATA GGTC 14425 14447 CCCCCATGCCTCAGGAT 2374 AGGAGTATCCTGAGGC 4143 ACTCCT ATGG 14426 14448 CCCCATGCCTCAGGATA 2375 GAGGAGTATCCTGAGG 4144 CTCCTC CATG 14427 14449 CCCATGCCTCAGGATAC 2376 TGAGGAGTATCCTGAG 4145 TCCTCA GCAT 14428 14450 CCATGCCTCAGGATACT 2377 TTGAGGAGTATCCTGA 4146 CCTCAA GGCA 14433 14455 CCTCAGGATACTCCTCA 2378 GGCTATTGAGGAGTAT 4147 ATAGCC CCTG 14445 14467 CCTCAATAGCCATCGCT 2379 TACTACAGCGATGGCT 4148 GTAGTA ATTG 14454 14476 CCATCGCTGTAGTATAT 2380 CTTTGGATATACTACA 4149 CCAAAG GCGA 14471 14493 CCAAAGACAACCATCAT 2381 GGGGGAATGATGGTTG 4150 TCCCCC TCTT 14481 14503 CCATCATTCCCCCTAAA 2382 AATTTATTTAGGGGGA 4151 TAAATT ATGA 14489 14511 CCCCCTAAATAAATTAA 2383 GTTTTTTTAATTTATTT 4152 AAAAAC AGG 14490 14512 CCCCTAAATAAATTAAA 2384 AGTTTTTTTAATTTATT 4153 AAAACT TAG 14491 14513 CCCTAAATAAATTAAAA 2385 TAGTTTTTTTAATTTAT 4154 AAACTA TTA 14492 14514 CCTAAATAAATTAAAAA 2386 ATAGTTTTTTTAATTTA 4155 AACTAT TTT 14519 14541 CCCATATAACCTCCCCC 2387 AATTTTGGGGGAGGTT 4156 AAAATT ATAT 14520 14542 CCATATAACCTCCCCCA 2388 GAATTTTGGGGGAGGT 4157 AAATTC TATA 14528 14550 CCTCCCCCAAAATTCAG 2389 ATTATTCTGAATTTTG 4158 AATAAT GGGG 14531 14553 CCCCCAAAATTCAGAAT 2390 GTTATTATTCTGAATTT 4159 AATAAC TGG 14532 14554 CCCCAAAATTCAGAATA 2391 TGTTATTATTCTGAATT 4160 ATAACA TTG 14533 14555 CCCAAAATTCAGAATAA 2392 GTGTTATTATTCTGAA 4161 TAACAC TTTT 14534 14556 CCAAAATTCAGAATAAT 2393 TGTGTTATTATTCTGA 4162 AACACA ATTT 14557 14579 CCCGACCACACCGCTAA 2394 TGATTGTTAGCGGTGT 4163 CAATCA GGTC 14558 14580 CCGACCACACCGCTAAC 2395 TTGATTGTTAGCGGTG 4164 AATCAA TGGT 14562 14584 CCACACCGCTAACAATC 2396 AGTATTGATTGTTAGC 4165 AATACT GGTG 14567 14589 CCGCTAACAATCAATAC 2397 GGTTTAGTATTGATTG 4166 TAAACC TTAG 14588 14610 CCCCCATAAATAGGAGA 2398 AAGCCTTCTCCTATTT 4167 AGGCTT ATGG 14589 14611 CCCCATAAATAGGAGA 2399 TAAGCCTTCTCCTATTT 4168 AGGCTTA ATG 14590 14612 CCCATAAATAGGAGAA 2400 CTAAGCCTTCTCCTAT 4169 GGCTTAG TTAT 14591 14613 CCATAAATAGGAGAAG 2401 TCTAAGCCTTCTCCTA 4170 GCTTAGA TTTA 14620 14642 CCCCACAAACCCCATTA 2402 GTTTAGTAATGGGGTT 4171 CTAAAC TGTG 14621 14643 CCCACAAACCCCATTAC 2403 GGTTTAGTAATGGGGT 4172 TAAACC TTGT 14622 14644 CCACAAACCCCATTACT 2404 GGGTTTAGTAATGGGG 4173 AAACCC TTTG 14629 14651 CCCCATTACTAAACCCA 2405 TGAGTGTGGGTTTAGT 4174 CACTCA AATG 14630 14652 CCCATTACTAAACCCAC 2406 TTGAGTGTGGGTTTAG 4175 ACTCAA TAAT 14631 14653 CCATTACTAAACCCACA 2407 GTTGAGTGTGGGTTTA 4176 CTCAAC GTAA 14642 14664 CCCACACTCAACAGAAA 2408 GCTTTGTTTCTGTTGA 4177 CAAAGC GTGT 14643 14665 CCACACTCAACAGAAAC 2409 TGCTTTGTTTCTGTTGA 4178 AAAGCA GTG 14694 14716 CCACGACCAATGATATG 2410 GTTTTTCATATCATTG 4179 AAAAAC GTCG 14700 14722 CCAATGATATGAAAAAC 2411 ACGATGGTTTTTCATA 4180 CATCGT TCAT 14716 14738 CCATCGTTGTATTTCAA 2412 TTGTAGTTGAAATACA 4181 CTACAA ACGA 14744 14766 CCAATGACCCCAATACG 2413 GTTTTGCGTATTGGGG 4182 CAAAAC TCAT 14751 14773 CCCCAATACGCAAAACT 2414 GGGGTTAGTTTTGCGT 4183 AACCCC ATTG 14752 14774 CCCAATACGCAAAACTA 2415 GGGGGTTAGTTTTGCG 4184 ACCCCC TATT 14753 14775 CCAATACGCAAAACTAA 2416 AGGGGGTTAGTTTTGC 4185 CCCCCT GTAT 14770 14792 CCCCCTAATAAAATTAA 2417 GGTTAATTAATTTTAT 4186 TTAACC TAGG 14771 14793 CCCCTAATAAAATTAAT 2418 TGGTTAATTAATTTTA 4187 TAACCA TTAG 14772 14794 CCCTAATAAAATTAATT 2419 GTGGTTAATTAATTTT 4188 AACCAC ATTA 14773 14795 CCTAATAAAATTAATTA 2420 AGTGGTTAATTAATTT 4189 ACCACT TATT 14791 14813 CCACTCATTCATCGACC 2421 TGGGGAGGTCGATGA 4190 TCCCCA ATGAG 14806 14828 CCTCCCCACCCCATCCA 2422 AGATGTTGGATGGGGT 4191 ACATCT GGGG 14809 14831 CCCCACCCCATCCAACA 2423 CGGAGATGTTGGATGG 4192 TCTCCG GGTG 14810 14832 CCCACCCCATCCAACAT 2424 GCGGAGATGTTGGATG 4193 CTCCGC GGGT 14811 14833 CCACCCCATCCAACATC 2425 TGCGGAGATGTTGGAT 4194 TCCGCA GGGG 14814 14836 CCCCATCCAACATCTCC 2426 TCATGCGGAGATGTTG 4195 GCATGA GATG 14815 14837 CCCATCCAACATCTCCG 2427 ATCATGCGGAGATGTT 4196 CATGAT GGAT 14816 14838 CCATCCAACATCTCCGC 2428 CATCATGCGGAGATGT 4197 ATGATG TGGA 14820 14842 CCAACATCTCCGCATGA 2429 GTTTCATCATGCGGAG 4198 TGAAAC ATGT 14829 14851 CCGCATGATGAAACTTC 2430 TGAGCCGAAGTTTCAT 4199 GGCTCA CATG 14854 14876 CCTTGGCGCCTGCCTGA 2431 GGAGGATCAGGCAGG 4200 TCCTCC CGCCA 14862 14884 CCTGCCTGATCCTCCAA 2432 GGTGATTTGGAGGATC 4201 ATCACC AGGC 14866 14888 CCTGATCCTCCAAATCA 2433 CTGTGGTGATTTGGAG 4202 CCACAG GATC 14872 14894 CCTCCAAATCACCACAG 2434 ATAGTCCTGTGGTGAT 4203 GACTAT TTGG 14875 14897 CCAAATCACCACAGGAC 2435 GGAATAGTCCTGTGGT 4204 TATTCC GATT 14883 14905 CCACAGGACTATTCCTA 2436 CATGGCTAGGAATAGT 4205 GCCATG CCTG 14896 14918 CCTAGCCATGCACTACT 2437 CTGGTGAGTAGTGCAT 4206 CACCAG GGCT 14901 14923 CCATGCACTACTCACCA 2438 GGCGTCTGGTGAGTAG 4207 GACGCC TGCA 14915 14937 CCAGACGCCTCAACCGC 2439 GAAAAGGCGGTTGAG 4208 CTTTTC GCGTC 14922 14944 CCTCAACCGCCTTTTCA 2440 GATTGATGAAAAGGC 4209 TCAATC GGTTG 14928 14950 CCGCCTTTTCATCAATC 2441 GTGGGCGATTGATGAA 4210 GCCCAC AAGG 14931 14953 CCTTTTCATCAATCGCC 2442 GATGTGGGCGATTGAT 4211 CACATC GAAA 14946 14968 CCCACATCACTCGAGAC 2443 ATTTACGTCTCGAGTG 4212 GTAAAT ATGT 14947 14969 CCACATCACTCGAGACG 2444 AATTTACGTCTCGAGT 4213 TAAATT GATG 14983 15005 CCGCTACCTTCACGCCA 2445 CGCCATTGGCGTGAAG 4214 ATGGCG GTAG 14989 15011 CCTTCACGCCAATGGCG 2446 TTGAGGCGCCATTGGC 4215 CCTCAA GTGA 14997 15019 CCAATGGCGCCTCAATA 2447 AAAGAATATTGAGGC 4216 TTCTTT GCCAT 15006 15028 CCTCAATATTCTTTATCT 2448 GAGGCAGATAAAGAA 4217 GCCTC TATTG 15025 15047 CCTCTTCCTACACATCG 2449 CTCGCCCGATGTGTAG 4218 GGCGAG GAAG 15031 15053 CCTACACATCGGGCGAG 2450 ATAGGCCTCGCCCGAT 4219 GCCTAT GTGT 15049 15071 CCTATATTACGGATCAT 2451 AGAGAAATGATCCGTA 4220 TTCTCT ATAT 15081 15103 CCTGAAACATCGGCATT 2452 GAGGATAATGCCGATG 4221 ATCCTC TTTC 15100 15122 CCTCCTGCTTGCAACTA 2453 TTGCTATAGTTGCAAG 4222 TAGCAA CAGG 15103 15125 CCTGCTTGCAACTATAG 2454 CTGTTGCTATAGTTGC 4223 CAACAG AAGC 15126 15148 CCTTCATAGGCTATGTC 2455 CGGGAGGACATAGCCT 4224 CTCCCG ATGA 15142 15164 CCTCCCGTGAGGCCAAA 2456 ATGATATTTGGCCTCA 4225 TATCAT CGGG 15145 15167 CCCGTGAGGCCAAATAT 2457 AGAATGATATTTGGCC 4226 CATTCT TCAC 15146 15168 CCGTGAGGCCAAATATC 2458 CAGAATGATATTTGGC 4227 ATTCTG CTCA 15154 15176 CCAAATATCATTCTGAG 2459 TGGCCCCTCAGAATGA 4228 GGGCCA TATT 15174 15196 CCACAGTAATTACAAAC 2460 TAGTAAGTTTGTAATT 4229 TTACTA ACTG 15198 15220 CCGCCATCCCATACATT 2461 TGTCCCAATGTATGGG 4230 GGGACA ATGG 15201 15223 CCATCCCATACATTGGG 2462 GTCTGTCCCAATGTAT 4231 ACAGAC GGGA 15205 15227 CCCATACATTGGGACAG 2463 CTAGGTCTGTCCCAAT 4232 ACCTAG GTAT 15206 15228 CCATACATTGGGACAGA 2464 ACTAGGTCTGTCCCAA 4233 CCTAGT TGTA 15223 15245 CCTAGTTCAATGAATCT 2465 CTCCTCAGATTCATTG 4234 GAGGAG AACT 15263 15285 CCCACCCTCACACGATT 2466 GTAAAGAATCGTGTGA 4235 CTTTAC GGGT 15264 15286 CCACCCTCACACGATTC 2467 GGTAAAGAATCGTGTG 4236 TTTACC AGGG 15267 15289 CCCTCACACGATTCTTT 2468 AAAGGTAAAGAATCG 4237 ACCTTT TGTGA 15268 15290 CCTCACACGATTCTTTA 2469 GAAAGGTAAAGAATC 4238 CCTTTC GTGTG 15285 15307 CCTTTCACTTCATCTTGC 2470 GAAGGGCAAGATGAA 4239 CCTTC GTGAA 15302 15324 CCCTTCATTATTGCAGC 2471 GCTAGGGCTGCAATAA 4240 CCTAGC TGAA 15303 15325 CCTTCATTATTGCAGCC 2472 TGCTAGGGCTGCAATA 4241 CTAGCA ATGA 15318 15340 CCCTAGCAACACTCCAC 2473 TAGGAGGTGGAGTGTT 4242 CTCCTA GCTA 15319 15341 CCTAGCAACACTCCACC 2474 ATAGGAGGTGGAGTGT 4243 TCCTAT TGCT 15331 15353 CCACCTCCTATTCTTGC 2475 TTTCGTGCAAGAATAG 4244 ACGAAA GAGG 15334 15356 CCTCCTATTCTTGCACG 2476 CCGTTTCGTGCAAGAA 4245 AAACGG TAGG 15337 15359 CCTATTCTTGCACGAAA 2477 ATCCCGTTTCGTGCAA 4246 CGGGAT GAAT 15367 15389 CCCCCTAGGAATCACCT 2478 AATGGGAGGTGATTCC 4247 CCCATT TAGG 15368 15390 CCCCTAGGAATCACCTC 2479 GAATGGGAGGTGATTC 4248 CCATTC CTAG 15369 15391 CCCTAGGAATCACCTCC 2480 GGAATGGGAGGTGATT 4249 CATTCC CCTA 15370 15392 CCTAGGAATCACCTCCC 2481 CGGAATGGGAGGTGA 4250 ATTCCG TTCCT 15381 15403 CCTCCCATTCCGATAAA 2482 GGTGATTTTATCGGAA 4251 ATCACC TGGG 15384 15406 CCCATTCCGATAAAATC 2483 GAAGGTGATTTTATCG 4252 ACCTTC GAAT 15385 15407 CCATTCCGATAAAATCA 2484 GGAAGGTGATTTTATC 4253 CCTTCC GGAA 15390 15412 CCGATAAAATCACCTTC 2485 AGGGTGGAAGGTGATT 4254 CACCCT TTAT 15402 15424 CCTTCCACCCTTACTAC 2486 GATTGTGTAGTAAGGG 4255 ACAATC TGGA 15406 15428 CCACCCTTACTACACAA 2487 CTTTGATTGTGTAGTA 4256 TCAAAG AGGG 15409 15431 CCCTTACTACACAATCA 2488 CGTCTTTGATTGTGTA 4257 AAGACG GTAA 15410 15432 CCTTACTACACAATCAA 2489 GCGTCTTTGATTGTGT 4258 AGACGC AGTA 15432 15454 CCCTCGGCTTACTTCTCT 2490 AAGGAAGAGAAGTAA 4259 TCCTT GCCGA 15433 15455 CCTCGGCTTACTTCTCTT 2491 GAAGGAAGAGAAGTA 4260 CCTTC AGCCG 15451 15473 CCTTCTCTCCTTAATGA 2492 TTAATGTCATTAAGGA 4261 CATTAA GAGA 15459 15481 CCTTAATGACATTAACA 2493 GAATAGTGTTAATGTC 4262 CTATTC ATTA 15485 15507 CCAGACCTCCTAGGCGA 2494 TCTGGGTCGCCTAGGA 4263 CCCAGA GGTC 15490 15512 CCTCCTAGGCGACCCAG 2495 AATTGTCTGGGTCGCC 4264 ACAATT TAGG 15493 15515 CCTAGGCGACCCAGACA 2496 TATAATTGTCTGGGTC 4265 ATTATA GCCT 15502 15524 CCCAGACAATTATACCC 2497 TGGCTAGGGTATAATT 4266 TAGCCA GTCT 15503 15525 CCAGACAATTATACCCT 2498 TTGGCTAGGGTATAAT 4267 AGCCAA TGTC 15516 15538 CCCTAGCCAACCCCTTA 2499 GGTGTTTAAGGGGTTG 4268 AACACC GCTA 15517 15539 CCTAGCCAACCCCTTAA 2500 GGGTGTTTAAGGGGTT 4269 ACACCC GGCT 15522 15544 CCAACCCCTTAAACACC 2501 GGGAGGGGTGTTTAAG 4270 CCTCCC GGGT 15526 15548 CCCCTTAAACACCCCTC 2502 TGTGGGGAGGGGTGTT 4271 CCCACA TAAG 15527 15549 CCCTTAAACACCCCTCC 2503 ATGTGGGGAGGGGTGT 4272 CCACAT TTAA 15528 15550 CCTTAAACACCCCTCCC 2504 GATGTGGGGAGGGGT 4273 CACATC GTTTA 15537 15559 CCCCTCCCCACATCAAG 2505 TTCGGGCTTGATGTGG 4274 CCCGAA GGAG 15538 15560 CCCTCCCCACATCAAGC 2506 ATTCGGGCTTGATGTG 4275 CCGAAT GGGA 15539 15561 CCTCCCCACATCAAGCC 2507 CATTCGGGCTTGATGT 4276 CGAATG GGGG 15542 15564 CCCCACATCAAGCCCGA 2508 TATCATTCGGGCTTGA 4277 ATGATA TGTG 15543 15565 CCCACATCAAGCCCGAA 2509 ATATCATTCGGGCTTG 4278 TGATAT ATGT 15544 15566 CCACATCAAGCCCGAAT 2510 AATATCATTCGGGCTT 4279 GATATT GATG 15554 15576 CCCGAATGATATTTCCT 2511 GCGAATAGGAAATATC 4280 ATTCGC ATTC 15555 15577 CCGAATGATATTTCCTA 2512 GGCGAATAGGAAATA 4281 TTCGCC TCATT 15568 15590 CCTATTCGCCTACACAA 2513 GGAGAATTGTGTAGGC 4282 TTCTCC GAAT 15576 15598 CCTACACAATTCTCCGA 2514 GACGGATCGGAGAATT 4283 TCCGTC GTGT 15589 15611 CCGATCCGTCCCTAACA 2515 CTAGTTTGTTAGGGAC 4284 AACTAG GGAT 15594 15616 CCGTCCCTAACAAACTA 2516 GCCTCCTAGTTTGTTA 4285 GGAGGC GGGA 15598 15620 CCCTAACAAACTAGGAG 2517 GGACGCCTCCTAGTTT 4286 GCGTCC GTTA 15599 15621 CCTAACAAACTAGGAG 2518 AGGACGCCTCCTAGTT 4287 GCGTCCT TGTT 15619 15641 CCTTGCCCTATTACTAT 2519 GGATGGATAGTAATAG 4288 CCATCC GGCA 15624 15646 CCCTATTACTATCCATC 2520 GATGAGGATGGATAGT 4289 CTCATC AATA 15625 15647 CCTATTACTATCCATCC 2521 GGATGAGGATGGATA 4290 TCATCC GTAAT 15636 15658 CCATCCTCATCCTAGCA 2522 GATTATTGCTAGGATG 4291 ATAATC AGGA 15640 15662 CCTCATCCTAGCAATAA 2523 TGGGGATTATTGCTAG 4292 TCCCCA GATG 15646 15668 CCTAGCAATAATCCCCA 2524 GGAGGATGGGGATTAT 4293 TCCTCC TGCT 15658 15680 CCCCATCCTCCATATAT 2525 GTTTGGATATATGGAG 4294 CCAAAC GATG 15659 15681 CCCATCCTCCATATATC 2526 TGTTTGGATATATGGA 4295 CAAACA GGAT 15660 15682 CCATCCTCCATATATCC 2527 TTGTTTGGATATATGG 4296 AAACAA AGGA 15664 15686 CCTCCATATATCCAAAC 2528 TTTGTTGTTTGGATAT 4297 AACAAA ATGG 15667 15689 CCATATATCCAAACAAC 2529 TGCTTTGTTGTTTGGAT 4298 AAAGCA ATA 15675 15697 CCAAACAACAAAGCAT 2530 AAATATTATGCTTTGT 4299 AATATTT TGTT 15700 15722 CCCACTAAGCCAATCAC 2531 AATAAAGTGATTGGCT 4300 TTTATT TAGT 15701 15723 CCACTAAGCCAATCACT 2532 CAATAAAGTGATTGGC 4301 TTATTG TTAG 15709 15731 CCAATCACTTTATTGAC 2533 CTAGGAGTCAATAAAG 4302 TCCTAG TGAT 15727 15749 CCTAGCCGCAGACCTCC 2534 GAATGAGGAGGTCTGC 4303 TCATTC GGCT 15732 15754 CCGCAGACCTCCTCATT 2535 GGTTAGAATGAGGAG 4304 CTAACC GTCTG 15739 15761 CCTCCTCATTCTAACCT 2536 CGATTCAGGTTAGAAT 4305 GAATCG GAGG 15742 15764 CCTCATTCTAACCTGAA 2537 CTCCGATTCAGGTTAG 4306 TCGGAG AATG 15753 15775 CCTGAATCGGAGGACA 2538 TACTGGTTGTCCTCCG 4307 ACCAGTA ATTC 15770 15792 CCAGTAAGCTACCCTTT 2539 ATGGTAAAAGGGTAG 4308 TACCAT CTTAC 15781 15803 CCCTTTTACCATCATTG 2540 CTTGTCCAATGATGGT 4309 GACAAG AAAA 15782 15804 CCTTTTACCATCATTGG 2541 ACTTGTCCAATGATGG 4310 ACAAGT TAAA 15789 15811 CCATCATTGGACAAGTA 2542 GGATGCTACTTGTCCA 4311 GCATCC ATGA 15810 15832 CCGTACTATACTTCACA 2543 GATTGTTGTGAAGTAT 4312 ACAATC AGTA 15832 15854 CCTAATCCTAATACCAA 2544 AGATAGTTGGTATTAG 4313 CTATCT GATT 15838 15860 CCTAATACCAACTATCT 2545 TTAGGGAGATAGTTGG 4314 CCCTAA TATT 15845 15867 CCAACTATCTCCCTAAT 2546 TTTTCAATTAGGGAGA 4315 TGAAAA TAGT 15855 15877 CCCTAATTGAAAACAAA 2547 GAGTATTTTGTTTTCA 4316 ATACTC ATTA 15856 15878 CCTAATTGAAAACAAAA 2548 TGAGTATTTTGTTTTCA 4317 TACTCA ATT 15885 15907 CCTGTCCTTGTAGTATA 2549 TTAGTTTATACTACAA 4318 AACTAA GGAC 15890 15912 CCTTGTAGTATAAACTA 2550 GTGTATTAGTTTATAC 4319 ATACAC TACA 15912 15934 CCAGTCTTGTAAACCGG 2551 TCATCTCCGGTTTACA 4320 AGATGA AGAC 15925 15947 CCGGAGATGAAAACCTT 2552 TGGAAAAAGGTTTTCA 4321 TTTCCA TCTC 15938 15960 CCTTTTTCCAAGGACAA 2553 TCTGATTTGTCCTTGG 4322 ATCAGA AAAA 15945 15967 CCAAGGACAAATCAGA 2554 CTTTTTCTCTGATTTGT 4323 GAAAAAG CCT 15977 15999 CCACCATTAGCACCCAA 2555 TTAGCTTTGGGTGCTA 4324 AGCTAA ATGG 15980 16002 CCATTAGCACCCAAAGC 2556 ATCTTAGCTTTGGGTG 4325 TAAGAT CTAA 15989 16011 CCCAAAGCTAAGATTCT 2557 TAAATTAGAATCTTAG 4326 AATTTA CTTT 15990 16012 CCAAAGCTAAGATTCTA 2558 TTAAATTAGAATCTTA 4327 ATTTAA GCTT 16052 16074 CCACCCAAGTATTGACT 2559 TGGGTGAGTCAATACT 4328 CACCCA TGGG 16055 16077 CCCAAGTATTGACTCAC 2560 TGATGGGTGAGTCAAT 4329 CCATCA ACTT 16056 16078 CCAAGTATTGACTCACC 2561 TTGATGGGTGAGTCAA 4330 CATCAA TACT 16071 16093 CCCATCAACAACCGCTA 2562 AATACATAGCGGTTGT 4331 TGTATT TGAT 16072 16094 CCATCAACAACCGCTAT 2563 AAATACATAGCGGTTG 4332 GTATTT TTGA 16082 16104 CCGCTATGTATTTCGTA 2564 GTAATGTACGAAATAC 4333 CATTAC ATAG 16107 16129 CCAGCCACCATGAATAT 2565 CGTACAATATTCATGG 4334 TGTACG TGGC 16111 16133 CCACCATGAATATTGTA 2566 GTACCGTACAATATTC 4335 CGGTAC ATGG 16114 16136 CCATGAATATTGTACGG 2567 ATGGTACCGTACAATA 4336 TACCAT TTCA 16133 16155 CCATAAATACTTGACCA 2568 TACAGGTGGTCAAGTA 4337 CCTGTA TTTA 16147 16169 CCACCTGTAGTACATAA 2569 GGGTTTTTATGTACTA 4338 AAACCC CAGG 16150 16172 CCTGTAGTACATAAAAA 2570 ATTGGGTTTTTATGTA 4339 CCCAAT CTAC 16167 16189 CCCAATCCACATCAAAA 2571 AGGGGGTTTTGATGTG 4340 CCCCCT GATT 16168 16190 CCAATCCACATCAAAAC 2572 GAGGGGGTTTTGATGT 4341 CCCCTC GGAT 16173 16195 CCACATCAAAACCCCCT 2573 ATGGGGAGGGGGTTTT 4342 CCCCAT GATG 16184 16206 CCCCCTCCCCATGCTTA 2574 TGCTTGTAAGCATGGG 4343 CAAGCA GAGG 16185 16207 CCCCTCCCCATGCTTAC 2575 TTGCTTGTAAGCATGG 4344 AAGCAA GGAG 16186 16208 CCCTCCCCATGCTTACA 2576 CTTGCTTGTAAGCATG 4345 AGCAAG GGGA 16187 16209 CCTCCCCATGCTTACAA 2577 ACTTGCTTGTAAGCAT 4346 GCAAGT GGGG 16190 16212 CCCCATGCTTACAAGCA 2578 TGTACTTGCTTGTAAG 4347 AGTACA CATG 16191 16213 CCCATGCTTACAAGCAA 2579 CTGTACTTGCTTGTAA 4348 GTACAG GCAT 16192 16214 CCATGCTTACAAGCAAG 2580 GCTGTACTTGCTTGTA 4349 TACAGC AGCA 16221 16243 CCCTCAACTATCACACA 2581 AGTTGATGTGTGATAG 4350 TCAACT TTGA 16222 16244 CCTCAACTATCACACAT 2582 CAGTTGATGTGTGATA 4351 CAACTG GTTG 16250 16272 CCAAAGCCACCCCTCAC 2583 TAGTGGGTGAGGGGTG 4352 CCACTA GCTT 16256 16278 CCACCCCTCACCCACTA 2584 GTATCCTAGTGGGTGA 4353 GGATAC GGGG 16259 16281 CCCCTCACCCACTAGGA 2585 TTGGTATCCTAGTGGG 4354 TACCAA TGAG 16260 16282 CCCTCACCCACTAGGAT 2586 GTTGGTATCCTAGTGG 4355 ACCAAC GTGA 16261 16283 CCTCACCCACTAGGATA 2587 TGTTGGTATCCTAGTG 4356 CCAACA GGTG 16266 16288 CCCACTAGGATACCAAC 2588 AGGTTTGTTGGTATCC 4357 AAACCT TAGT 16267 16289 CCACTAGGATACCAACA 2589 TAGGTTTGTTGGTATC 4358 AACCTA CTAG 16278 16300 CCAACAAACCTACCCAC 2590 TTAAGGGTGGGTAGGT 4359 CCTTAA TTGT 16286 16308 CCTACCCACCCTTAACA 2591 ATGTACTGTTAAGGGT 4360 GTACAT GGGT 16290 16312 CCCACCCTTAACAGTAC 2592 TACTATGTACTGTTAA 4361 ATAGTA GGGT 16291 16313 CCACCCTTAACAGTACA 2593 GTACTATGTACTGTTA 4362 TAGTAC AGGG 16294 16316 CCCTTAACAGTACATAG 2594 TATGTACTATGTACTG 4363 TACATA TTAA 16295 16317 CCTTAACAGTACATAGT 2595 TTATGTACTATGTACT 4364 ACATAA GTTA 16320 16342 CCATTTACCGTACATAG 2596 AATGTGCTATGTACGG 4365 CACATT TAAA 16327 16349 CCGTACATAGCACATTA 2597 TGACTGTAATGTGCTA 4366 CAGTCA TGTA 16353 16375 CCCTTCTCGTCCCCATG 2598 GTCATCCATGGGGACG 4367 GATGAC AGAA 16354 16376 CCTTCTCGTCCCCATGG 2599 GGTCATCCATGGGGAC 4368 ATGACC GAGA 16363 16385 CCCCATGGATGACCCCC 2600 TCTGAGGGGGGTCATC 4369 CTCAGA CATG 16364 16386 CCCATGGATGACCCCCC 2601 ATCTGAGGGGGGTCAT 4370 TCAGAT CCAT 16365 16387 CCATGGATGACCCCCCT 2602 TATCTGAGGGGGGTCA 4371 CAGATA TCCA 16375 16397 CCCCCCTCAGATAGGGG 2603 AAGGGACCCCTATCTG 4372 TCCCTT AGGG 16376 16398 CCCCCTCAGATAGGGGT 2604 CAAGGGACCCCTATCT 4373 CCCTTG GAGG 16377 16399 CCCCTCAGATAGGGGTC 2605 TCAAGGGACCCCTATC 4374 CCTTGA TGAG 16378 16400 CCCTCAGATAGGGGTCC 2606 GTCAAGGGACCCCTAT 4375 CTTGAC CTGA 16379 16401 CCTCAGATAGGGGTCCC 2607 GGTCAAGGGACCCCTA 4376 TTGACC TCTG 16393 16415 CCCTTGACCACCATCCT 2608 TCACGGAGGATGGTGG 4377 CCGTGA TCAA 16394 16416 CCTTGACCACCATCCTC 2609 TTCACGGAGGATGGTG 4378 CGTGAA GTCA 16400 16422 CCACCATCCTCCGTGAA 2610 ATTGATTTCACGGAGG 4379 ATCAAT ATGG 16403 16425 CCATCCTCCGTGAAATC 2611 GATATTGATTTCACGG 4380 AATATC AGGA 16407 16429 CCTCCGTGAAATCAATA 2612 GCGGGATATTGATTTC 4381 TCCCGC ACGG 16410 16432 CCGTGAAATCAATATCC 2613 TGTGCGGGATATTGAT 4382 CGCACA TTCA 16425 16447 CCCGCACAAGAGTGCTA 2614 GGAGAGTAGCACTCTT 4383 CTCTCC GTGC 16426 16448 CCGCACAAGAGTGCTAC 2615 AGGAGAGTAGCACTCT 4384 TCTCCT TGTG 16446 16468 CCTCGCTCCGGGCCCAT 2616 AGTGTTATGGGCCCGG 4385 AACACT AGCG 16453 16475 CCGGGCCCATAACACTT 2617 ACCCCCAAGTGTTATG 4386 GGGGGT GGCC 16458 16480 CCCATAACACTTGGGGG 2618 TAGCTACCCCCAAGTG 4387 TAGCTA TTAT 16459 16481 CCATAACACTTGGGGGT 2619 TTAGCTACCCCCAAGT 4388 AGCTAA GTTA 16494 16516 CCGACATCTGGTTCCTA 2620 CTGAAGTAGGAACCA 4389 CTTCAG GATGT 16507 16529 CCTACTTCAGGGTCATA 2621 AGGCTTTATGACCCTG 4390 AAGCCT AAGT 16527 16549 CCTAAATAGCCCACACG 2622 GGGGAACGTGTGGGCT 4391 TTCCCC ATTT 16536 16558 CCCACACGTTCCCCTTA 2623 CTTATTTAAGGGGAAC 4392 AATAAG GTGT 16537 16559 CCACACGTTCCCCTTAA 2624 TCTTATTTAAGGGGAA 4393 ATAAGA CGTG 16546 16568 CCCCTTAAATAAGACAT 2625 ATCGTGATGTCTTATT 4394 CACGAT TAAG 16547 16569 CCCTTAAATAAGACATC 2626 CATCGTGATGTCTTAT 4395 ACGATG TTAA 16548 16570 CCTTAAATAAGACATCA 2627 CCATCGTGATGTCTTA 4396 CGATGG TTTA Applications

The gNAs (e.g., gRNAs) and collections of gNAs (e.g., gRNAs) provided herein are useful for a variety of applications, including depletion, partitioning, capture, or enrichment of target sequences of interest; genome-wide labeling; genome-wide editing; genome-wide function screens; and genome-wide regulation.

In one embodiment, the gNAs are selective for host nucleic acids in a biological sample from a host, but are not selective for non-host nucleic acids in the sample from a host. In one embodiment, the gNAs are selective for non-host nucleic acids from a biological sample from a host but are not selective for the host nucleic acids in the sample. In one embodiment, the gNAs are selective for both host nucleic acids and a subset of the non-host nucleic acids in a biological sample from a host. For example, where a complex biological sample comprises host nucleic acids and nucleic acids from more than one non-host organisms, the gRNAs may be selective for more than one of the non-host species. In such embodiments, the gNAs are used to serially deplete or partition the sequences that are not of interest. For example, saliva from a human contains human DNA, as well as the DNA of more than one bacterial species, but may also contain the genomic material of an unknown pathogenic organism. In such an embodiment, gNAs directed at the human DNA and the known bacteria can be used to serially deplete the human DNA, and the DNA of the known bacterial, thus resulting in a sample comprising the genomic material of the unknown pathogenic organism.

In an exemplary embodiment, the gNAs are selective for human host DNA obtained from a biological sample from the host, but do not hybridize with DNA from an unknown pathogen(s) also obtained from the sample.

In some embodiments, the gNAs are useful for depleting and partitioning of targeted sequences in a sample, enriching a sample for non-host nucleic acids, or serially depleting targeted nucleic acids in a sample comprising: providing nucleic acids extracted from a sample; and contacting the sample with a plurality of complexes comprising (i) any one of the collection of gNAs described herein and (ii) nucleic acid-guided nuclease (e.g., CRISPR/Cas) system proteins.

In some embodiments, the gNAs are useful for method of depletion and partitioning of targeted sequences in a sample comprising: providing nucleic acids extracted from a sample, wherein the extracted nucleic acids comprise sequences of interest and targeted sequences for one of depletion and partitioning; contacting the sample with a plurality of complexes comprising (i) a collection of gNAs provided herein; and (ii) nucleic acid-guided nuclease (e.g., CRISPR/Cas) system proteins, under conditions in which the nucleic acid-guided nuclease system proteins cleave the nucleic acids in the sample.

In some embodiments, the gNAs are useful for enriching a sample for non-host nucleic acids comprising: providing a sample comprising host nucleic acids and non-host nucleic acids; contacting the sample with a plurality of complexes comprising (i) a collection of gNAs provided herein comprising targeting sequences directed at the host nucleic acids; and (ii) nucleic acid-guided nuclease (e.g., CRISPR/Cas) system proteins, under conditions in which the nucleic acid-guided nuclease system proteins cleave the host nucleic acids in the sample, thereby depleting the sample of host nucleic acids, and allowing for the enrichment of non-host nucleic acids.

In some embodiments, the gNAs are useful for one method for serially depleting targeted nucleic acids in a sample comprising: providing a biological sample from a host comprising host nucleic acids and non-host nucleic acids, wherein the non-host nucleic acids comprise nucleic acids from at least one known non-host organism and nucleic acids from an unknown non-host organism; providing a plurality of complexes comprising (i) a collection of gNAs provided herein, directed at the host nucleic acids; and (ii) nucleic acid-guided nuclease (e.g., CRISPR/Cas) system proteins; mixing the nucleic acids from the biological sample with the gNA-nucleic acid-guided nuclease system protein complexes (e.g., gRNA-CRISPR/Cas system protein complexes) configured to hybridize to targeted sequences in the host nucleic acids, wherein at least a portion of the complexes hybridizes to the targeted sequences in the host nucleic acids, and wherein at least a portion of the host nucleic acids are cleaved; mixing the remaining nucleic acids from the biological sample with the gNA-nucleic acid-guided nuclease system protein complexes configured to hybridize to targeted sequences in the at least one known non-host nucleic acids, wherein at least a portion of the complexes hybridizes to the targeted sequences in the at least one non-host nucleic acids, and wherein at least a portion of the non-host nucleic acids are cleaved; and isolating the remaining nucleic acids from the unknown non-host organism and preparing for further analysis.

In some embodiments, the gNAs generated herein are used to perform genome-wide or targeted functional screens in a population of cells. In such an embodiment, libraries of in vitro-transcribed gNAs (e.g., gRNAs) or vectors encoding the gNAs can be introduced into a population of cells via transfection or other laboratory techniques known in the art, along with a nucleic acid-guided nuclease (e.g., CRISPR/Cas) system protein, in a way that gNA-directed nucleic acid-guided nuclease system protein editing can be achieved to sequences across the entire genome or to a specific region of the genome. In one embodiment, the nucleic acid-guided nuclease system protein can be introduced as a DNA. In one embodiment, the nucleic acid-guided nuclease system protein can be introduced as mRNA. In one embodiment, the nucleic acid-guided nuclease system protein can be introduced as protein. In one exemplary embodiment, the nucleic acid-guided nuclease system protein is Cas9.

In some embodiments, the gNAs generated herein are used for the selective capture and/or enrichment of nucleic acid sequences of interest. For example, in some embodiments, the gNAs generated herein are used for capturing target nucleic acid sequences comprising: providing a sample comprising a plurality of nucleic acids; and contacting the sample with a plurality of complexes comprising (i) a collection of gNAs provided herein; and (ii) nucleic acid-guided nuclease (e.g., CRISPR/Cas) system proteins. Once the sequences of interest are captured, they can be further ligated to create, for example, a sequencing library.

In some embodiments, the gNAs generated herein are used for introducing labeled nucleotides at targeted sites of interest comprising: (a) providing a sample comprising a plurality of nucleic acid fragments; (b) contacting the sample with a plurality of complexes comprising (i) a collection of gNAs provided herein; and (ii) nucleic acid-guided nuclease (e.g., CRISPR/Cas) system protein-nickases (e.g. Cas9-nickases), wherein the gNAs are complementary to targeted sites of interest in the nucleic acid fragments, thereby generating a plurality of nicked nucleic acid fragments at the targeted sites of interest; and (c) contacting the plurality of nicked nucleic acid fragments with an enzyme capable of initiating nucleic acid synthesis at a nicked site, and labeled nucleotides, thereby generating a plurality of nucleic acid fragments comprising labeled nucleotides in the targeted sites of interest.

In some embodiments, the gNAs generated herein are used for capturing target nucleic acid sequences of interest comprising: (a) providing a sample comprising a plurality of adapter-ligated nucleic acids, wherein the nucleic acids are ligated to a first adapter at one end and are ligated to a second adapter at the other end; and (b) contacting the sample with a collection of gNAs which comprise a plurality of dead nucleic acid-guided nuclease-gNA complexes (e.g., dCas9-gRNA complexes), wherein the dead nucleic acid-guided nuclease (e.g., dCas9) is fused to a transposase, wherein the gNAs are complementary to targeted sites of interest contained in a subset of the nucleic acids, and wherein the dead nucleic acid-guided nuclease-gNA transposase complexes (e.g., dCas9-gRNA transposase complexes) are loaded with a plurality of third adapters, to generate a plurality of nucleic acids fragments comprising either a first or second adapter at one end and a third adapter at the other end. In one embodiment the method further comprises amplifying the product of step (b) using first or second adapter and third adapter-specific PCR.

In some embodiments, the gNAs generated herein are used to perform genome-wide or targeted activation or repression in a population of cells. In such an embodiment, libraries of in vitro-transcribed gNAs (e.g., gRNAs) or vectors encoding the gNAs can be introduced into a population of cells via transfection or other laboratory techniques known in the art, along with a catalytically dead nucleic acid-guided nuclease (e.g., CRISPR/Cas) system protein fused to an activator or repressor domain (catalytically dead nucleic acid-guided nuclease system protein-fusion protein), in a way that gNA-directed catalytically dead nucleic acid-guided nuclease system protein-mediated activation or repression can be achieved at sequences across the entire genome or to a specific region of the genome. In one embodiment, the catalytically dead nucleic acid-guided nuclease system protein-fusion protein can be introduced as DNA. In one embodiment, the catalytically dead nucleic acid-guided nuclease system protein-fusion protein can be introduced as mRNA. In one embodiment, the catalytically dead nucleic acid-guided nuclease system protein-fusion protein can be introduced as protein. In some embodiments, the collection of gNAs or nucleic acids encoding for gNAs exhibit specificity for more than one nucleic acid-guided nuclease system protein. In one exemplary embodiment, the catalytically dead nucleic acid-guided nuclease system protein is dCas9.

In some embodiments, the collection comprises gRNAs or nucleic acids encoding for gRNAs with specificity for Cas9 and one or more CRISPR/Cas system proteins selected from selected from the group consisting of Cpf1, Cas3, Cas8a-c, Cas10, Cse1, Csy1, Csn2, Cas4, Csm2, and Cm5. In some embodiments, the collection comprises gRNAs or nucleic acids encoding for gRNAs with specificity for various catalytically dead CRISPR/Cas system proteins fused to different fluorophores, for example for use in the labeling and/or visualization of different genomes or portions of genomes, for use in the labeling and/or visualization of different chromosomal regions, or for use in the labeling and/or visualization of the integration of viral genes/genomes into a genome.

In some embodiments, the collection of gNAs (or nucleic acids encoding for gNAs) have specificity for different nucleic acid-guided nuclease (e.g., CRISPR/Cas) system proteins, and target different sequences of interest, for example from different species. For example, a first subset of gNAs from a collection of gNAs (or transcribed from a population of nucleic acids encoding such gNAs) targeting a genome from a first species can be first mixed with a first nucleic acid-guided nuclease system protein member (or an engineered version); and a second subset of gNAs from a collection of gNAs (or transcribed from a population of nucleic acids encoding such gNAs) targeting a genome from a second species can be mixed with a second different nucleic acid-guided nuclease system protein member (or an engineered version). In one embodiment, the nucleic acid-guided nuclease system proteins can be a catalytically dead version (for example dCas9) fused with different fluorophores, so that different targeted sequence of interest, e.g. different species genome, or different chromosomes of one species, can be labeled by different fluorescent labels. For example, different chromosomal regions can be labeled by different gRNA-targeted dCas9-fluorophores, for visualization of genetic translocations. For example, different viral genomes can be labeled by different gRNA-targeted dCas9-fluorophores, for visualization of integration of different viral genomes into the host genome. In another embodiment, the nucleic acid-guided nuclease system protein can be dCas9 fused with either activation or repression domain, so that different targeted sequence of interest, e.g. different chromosomes of a genome, can be differentially regulated. In another embodiment, the nucleic acid-guided nuclease system protein can be dCas9 fused different protein domain which can be recognized by different antibodies, so that different targeted sequence of interest, e.g. different DNA sequences within a sample mixture, can be differentially isolated.

Exemplary Compositions of the Invention

In one embodiment, provided herein is a composition comprising a nucleic acid fragment, a nickase nucleic acid-guided nuclease-gNA complex, and labeled nucleotides. In one exemplary embodiment, provided herein is a composition comprising a nucleic acid fragment, a nickase Cas9-gRNA complex, and labeled nucleotides. In such embodiments, the nucleic acid may comprise DNA. The nucleotides can be labeled, for example with biotin. The nucleotides can be part of an antibody-conjugate pair.

In one embodiment, provided herein is a composition comprising a nucleic acid fragment and a catalytically dead nucleic acid-guided nuclease-gNA complex, wherein the catalytically dead nucleic acid-guided nuclease is fused to a transposase. In one exemplary embodiment, provided herein is a composition comprising a DNA fragment and a dCas9-gRNA complex, wherein the dCas9 is fused to a transposase.

In one embodiment, provided herein is a composition comprising a nucleic acid fragment comprising methylated nucleotides, a nickase nucleic acid-guided nuclease-gNA complex, and unmethylated nucleotides. In an exemplary embodiment, provided herein is a composition comprising a DNA fragment comprising methylated nucleotides, a nickase Cas9-gRNA complex, and unmethylated nucleotides.

In one embodiment, provided herein is a gDNA complexed with a nucleic acid-guided-DNA endonuclease. In an exemplary embodiment, the nucleic acid-guided-DNA endonuclease is NgAgo.

In one embodiment, provided herein is a gDNA complexed with a nucleic acid-guided-RNA endonuclease.

In one embodiment, provided herein is a gRNA complexed with a nucleic acid-guided-DNA endonuclease.

In one embodiment, provided herein is a gRNA complexed with a nucleic acid-guided-RNA endonuclease. In one embodiment, the nucleic acid-guided-RNA endonuclease comprises C2c2.

Kits and Articles of Manufacture

The present application provides kits comprising any one or more of the compositions described herein, not limited to adapters, gNAs (e.g., gRNAs), gNA collections (e.g., gRNA collections), nucleic acid molecules encoding the gNA collections, and the like.

In one exemplary embodiment, the kit comprises a collection of DNA molecules capable of transcribing into a library of gRNAs wherein the gRNAs are targeted to human genomic or other sources of DNA sequences.

In one embodiment, the kit comprises a collection of gNAs wherein the gNAs are targeted to human genomic or other sources of DNA sequences.

In some embodiments, provided herein are kits comprising any of the collection of nucleic acids encoding gNAs, as described herein. In some embodiments, provided herein are kits comprising any of the collection of gNAs, as described herein.

The present application also provides all essential reagents and instructions for carrying out the methods of making the gNAs and the collection of nucleic acids encoding gNAs, as described herein. In some embodiments, provided herein are kits that comprise all essential reagents and instructions for carrying out the methods of making individual gNAs and collections of gNAs as described herein.

Also provided herein is computer software monitoring the information before and after contacting a sample with a gNA collection produced herein. In one exemplary embodiment, the software can compute and report the abundance of non-target sequence in the sample before and after providing gNA collection to ensure no off-target targeting occurs, and wherein the software can check the efficacy of targeted-depletion/encrichment/capture/partitioning/labeling/regulation/editing by comparing the abundance of the target sequence before and after providing gNA collection to the sample.

The following examples are included for illustrative purposes and are not intend to limit the scope of the invention.

EXAMPLES Example 1: Construction of a gRNA Library from a T7 Promoter Human DNA Library

T7 Promoter Library Construction

Human genomic DNA (400 ng) was fragmented using an S2 Covaris sonicator (Covaris) for 8 cycles, to yield fragments of 200-300 bp in length. Fragmented DNA was repaired using the NEBNext End Repair Module (NEB) and incubated at 25° C. for 30 min, then heat inactivated at 75° C. for 20 min. To make T7 promoter adapters, oligos T7-1 (5′GCCTCGAGC*T*A*ATACGACTCACTATAGAG3′, * denotes a phosphorothioate backbone linkage)(SEQ ID NO: 4397) and T7-2 (sequence 5′Phos-CTCTATAGTGAGTCGTATTA3′) (SEQ ID NO: 4398) were admixed at 15 μM, heated to 98° C. for 3 min then cooled slowly (0.1° C./min) to 30° C. T7 promoter blunt adapters (15 pmol total) were then added to the blunt-ended human genomic DNA fragments, and incubated with Blunt/TA Ligase Master Mix (NEB) at 25° C. for 30 min ((2) in FIG. 1). Ligations were amplified with 2 μM oligo T7-1, using Hi-Fidelity 2× Master Mix (NEB) for 10 cycles of PCR (98° C. for 20 s, 63° C. for 20 s, 72° C. for 35 s). Amplification was verified by running a small aliquot on agarose gel electrophoresis. PCR amplified products were recovered using 0.6× AxyPrep beads (Axygen) according to the manufacturer's instructions, and resuspended in 15 μL of 10 mM Tris-HCl pH 8.

Digestion of DNA

PCR amplified T7 promoter DNA (2 μg total per digestion) was digested with 0.1 μL of Nt.CviPII (NEB) in 10 μL of NEB buffer 2 (50 mM NaCl, 10 mM Tris-HCl pH 7.9, 10 mM MgCl₂, 100 μg/mL BSA) for 10 min at 37° C. ((3) in FIG. 1), then heat inactivated at 75° C. for 20 min. An additional 10 μL of NEB buffer 2 with 1 μL of T7 Endonuclease I (NEB) was added to the reaction, and incubated at 37° C. for 20 min ((4) in FIG. 1). Enzymatic digestion of DNA was verified by agarose gel electrophoresis. Digested DNA was recovered by adding 0.6× AxyPrep beads (Axygen), according to the manufacturer's instructions, and resuspended in 15 μL of 10 mM Tris-HCl pH 8.

Ligation of Adapters and Removal of HGG

DNA was then blunted using T4 DNA Polymerase (NEB) for 20 min at 25° C., followed by heat inactivation at 75° C. for 20 min ((5) in FIG. 1).

To make MlyI adapters, oligos MlyI-1 (sequence 5′>3′, 5′Phos-GGGACTCGGATCCCTATAGTGATACAAAGACGATGACGACAAGCG) (SEQ ID NO: 4399) and MlyI-2 (sequence 5′>3′, TCACTATAGGGATCCGAGTCCC) (SEQ ID NO: 4400) were admixed at 15 μM, heated to 98° C. for 3 min then cooled slowly (0.1° C./min) to 30° C. MlyI adapters (15 pmol total) were then added to T4 DNA Polymerase-blunted DNA, and incubated with Blunt/TA Ligase Master Mix (NEB) at 25° C. for 30 min ((6) in FIG. 1). Ligations were heat inactivated at 75° C. for 20 min, then digested with MlyI and XhoI (NEB) for 1 hr at 37° C., so that HGG motifs are eliminated ((7) in FIG. 1). Digests were then cleaned using 0.8× AxyPrep beads (Axygen), and DNA was resuspended in 10 μL of 10 mM Tris-Cl pH 8.

To make StlgR adapters, oligos stlgR (sequence 5′>3′, 5′Phos-GTTTTAGAGCTAGAAATAGCAAGTTAAAATAAGGCTAGTCCGTTATCAACTTGAAAAAGTGGCACCG AGTCGGTGCTTTTTTTGGATCCGATGC) (SEQ ID NO: 4401) and stlgRev (sequence 5′>3′, GGATCCAAAAAAAGCACCGACTCGGTGCCACTTTTTCAAGTTGATAACGGACTAGCCTTATTTTAAC TTGCTATTTCTAGCTCTAAAAC) (SEQ ID NO: 4402) were admixed at 15 μM, heated to 98° C. for 3 min then cooled slowly (0.1° C./min) to 60° C. StlgR adapters (5 pmol total) were added to HGG-removed DNA fragments, and incubated with Blunt/TA Ligase Master Mix (NEB) at 25° C. for 30 min ((8) in FIG. 1). Ligations were then incubated with Hi-Fidelity 2× Master Mix (NEB), using 2 μM of both oligos T7-1 and gRU (sequence 5′>3′, AAAAAAAGCACCGACTCGGTG) (SEQ ID NO: 4403), and amplified using 20 cycles of PCR (98° C. for 20 s, 60° C. for 20 s, 72° C. for 35 s). Amplification was verified by running a small aliquot on agarose gel electrophoresis. PCR amplified products were recovered using 0.6× AxyPrep beads (Axygen) according to the manufacturer's instructions, and resuspended in 15 μL of 10 mM Tris-HCl pH 8.

In Vitro Transcription

The T7/gRU amplified library of PCR products was then used as template for in vitro transcription, using the HiScribe T7 In Vitro Transcription Kit (NEB). 500-1000 ng of template was incubated overnight at 37° C. according to the manufacturer's instructions. To transcribe the guide libraries into gRNAs, the following in vitro transcription reaction mixture was assembled: 10 μL of purified library (˜500 ng), 6.5 μL of H₂O, 2.25 μL of ATP, 2.25 μL of CTP, 2.25 μL of GTP, 2.25 μL of UTP, 2.25 μL of 10× reaction buffer (NEB) and 2.25 μL of T7 RNA Polymerase mix. The reaction was incubated at 37° C. for 24 hr, then purified using the RNA cleanup kit (Life Technologies), eluted with 100 μL of RNase-free water, quantified and stored at −20° C. until use.

Example 2: Construction of gRNA Library from Intact Human Genomic DNA

Digestion of DNA

Human genomic DNA ((1) in FIG. 2; 20 μg total per digestion) was digested with 0.1 μL of Nt.CviPII (NEB) in 40 μL of NEB buffer 2 (50 mM NaCl, 10 mM Tris-HCl pH 7.9, 10 mM MgCl₂, 100 μg/mL BSA) for 10 min at 37° C., then heat inactivated at 75° C. for 20 min. An additional 40 μL of NEB buffer 2 and 1 μL of T7 Endonuclease I (NEB) was added to the reaction, with 20 min incubation at 37° C. (e.g., (2) in FIG. 2). Fragmentation of genomic DNA was verified with a small aliquot by agarose gel electrophoresis. DNA fragments between 200 and 600 bp were recovered by adding 0.3× AxyPrep beads (Axygen), incubating at 25° C. for 5 min, capturing beads on a magnetic stand and transferring the supernatant to a new tube. DNA fragments below 600 bp do not bind to beads at this bead/DNA ratio and remain in the supernatant. 0.7× AxyPrep beads (Axygen) were then added to the supernatant (this will bind all DNA molecules longer than 200 bp), allowed to bind for 5 min. Beads were captured on a magnetic stand and washed twice with 80% ethanol, air dried. DNA was then resuspended in 15 μL of 10 mM Tris-HCl pH 8. DNA concentration was determined using a Qbit assay (Life Technologies).

Ligation of Adapters

To make T7/MlyI adapters, oligos MlyI-1 (sequence 5′>3′, 5′Phos-GGGGGACTCGGATCCCTATAGTGATACAAAGACGATGACGACAAGCG) (SEQ ID NO: 4404) and T7-7 (sequence 5′>3′, GCCTCGAGC*T*A*ATACGACTCACTATAGGGATCCAAGTCCC, * denotes a phosphorothioate backbone linkage) (SEQ ID NO: 4405) were admixed at 15 μM, heated to 98° C. for 3 min then cooled slowly (0.1° C./min) to 30° C. The purified, Nt.CviPII/T7 Endonuclease I digested DNA (100 ng) was then ligated to 15 pmol of T7/MlyI adapters using Blunt/TA Ligase Master Mix (NEB) at 25° C. for 30 min ((3) in FIG. 2). Ligations were then amplified by 10 cycles of PCR (98° C. for 20 s, 60° C. for 20 s, 72° C. for 35 s) using Hi-Fidelity 2× Master Mix (NEB), and 2 μM of both oligos T7-17 (GCCTCGAGC*T*A*ATACGACTCACTATAGGG * denotes a phosphorothioate backbone linkage) (SEQ ID NO: 4406) and Flag (sequence 5′>3′, CGCTTGTCGTCATCGTCTTTGTA) (SEQ ID NO: 4407). PCR amplification increases the yield of DNA and, given the nature of the Y-shaped adapters we used, always resulted in T7 promoter being added distal to the HGG site and MlyI site being added next to the HGG motif ((4) in FIG. 2).

PCR products were then digested with MlyI and XhoI (NEB) for 1 hr at 37° C., and heat inactivated at 75° C. for 20 min ((5) in FIG. 2). Following that, 5 pmol of adapter StlgR (in Example 1) was ligated using Blunt/TA Ligase Master Mix (NEB) at 25° C. for 30 min ((6) in FIG. 2). Ligations were then amplified by PCR using Hi-Fidelity 2× Master Mix (NEB), 2 μM of both oligos T7-7 and gRU (in Example 1) and 20 cycles of PCR (98° C. for 20 s, 60° C. for 20 s, 72° C. for 35 s). Amplification was verified by running a small aliquot on agarose gel electrophoresis. PCR amplified products were recovered using 0.6× AxyPrep beads (Axygen) according to the manufacturer's instructions, and resuspended in 15 μL of 10 mM Tris-HCl pH 8.

Samples were then used as templates for in vitro transcription reaction as described in Example 1.

Example 3: Direct Cutting with CviPII

30 μg of human genomic DNA was digested with 2 units of NtCviPII (New England Biolabs) for 1 hour at 37° C., followed by heat inactivation at 75° C. for 20 minutes. The size of the fragments was verified to be 200-1,000 base pairs using a fragment analyzer instrument (Advanced Analytical). The 5′ or 3′ protruding ends (as shown, for example, in FIG. 3) were converted to blunt ends by adding 100 units of T4 DNA polymerase (New England Biolabs), 100 μM dNTPs and incubating at 12° C. for 30 minutes. DNA was then recovered using a PCR cleanup kit (Zymo) and eluted in 20 μL elution buffer. The DNA was then ligated to MlyI adapter (see, for example, Example 4) or BaeI/EcoP15I adapters (see, for example, Example 4) or BaeI/EcoP15I adapters (see, for example, Example 5)

Example 4: Use of MlyI Adapter

Adapter MlyI was made by combining 2 μmoles of MlyI Ad1 and MlyAd2 in 40 μL water. Adapter BsaXI/MmeI was made by combining 2 moles oligo BsMm-Ad1 and 2 moles oligo BsMm-Ad2 in 40 μL water. T7 adapter was made by combining 1.5 μmoles of T7-Ad1 and T7-Ad2 oligos in 100 μL water. Stem-loop adapter was made by combining 1.5 μmoles of gR-top and gR-bot oligos in 100 μL water. In all cases, after mixing adapters were heated to 98° C. for 3 min then cooled to room temperature at a cooling rate of 1° C./min in a thermal cycler.

TABLE 5 Oligonucleotides used with MlyI Adapter. SEQ Oligo ID NO name Sequence (5′ > 3′) Modification 4408 MlyI- gagatcagcttctgcattgatgccagcagcccgagtcag none Ad1 4409 MlyI- ctgactcgggctgctgtacaaagacgatgacgacaagcgtta 5′phosphate Ad2 4410 BsMm- gagatcagcttctgcattgatgcGGAGCCGCAGTACACTATCCAAC none Ad1 4411 BsMm- GTTGGATAGTGTACTGCGGCTCCtacaaagacgatgacgacaagcg 5′phosphate Ad2 4412 T7-Ad1 gcctcgagctaatacgactcactatagagNN none 4398 T7-Ad2 Ctctatagtgagtcgtatta 5′phosphate 4413 gR-top ttagagctagaaatagcaagttaaaataaggctagtccgttatcaa 5′phosphate cttgaaaaagtggcaccgatcggtgctttttt 4414 gR-bot aaaaaagcaccgactcggtgccactttttcaagttgataacggact none agccttattttaacttgctatttctagctctaaaac

The DNA containing the CCD blunt ends (from earlier section) was then ligated to 50 pmoles of adapter MlyI, using the blunt/TA ligation master mix (New England Biolabs) at room temperature for 30 minutes. The DNA was then recovered by incubating with 0.6× Kapa SPRI beads (Kapa Biosystems) for 5 minutes, capturing the beads with a magnetic rack, washing twice with 80% ethanol, air drying the beads for 5 minutes and finally resuspending the DNA in 50 μL buffer 4 (50 mM potassium acetate, 20 mM Tris-acetate, 10 mM magnesium acetate, 100 μg/mL BSA, pH 7.9). These steps eliminate small (<100 nucleotides) DNA and MlyI adapter dimers.

Purified DNA was then digested by adding 20 units of MlyI (New England Biolabs) and incubating at 37° C. for 1 hour to eliminate both the adapter derived sequences and the CCD (and complementary HGG) motifs. DNA was recovered from the digest by incubating with 0.6× Kapa SPRI beads (Kapa Biosystems) for 5 minutes, capturing the beads with a magnetic rack, washing twice with 80% ethanol, air drying the beads for 5 minutes and finally resuspending the DNA in 30 μL buffer 4.

The purified DNA was then ligated to 50 pmoles of adapter BsaXI/MmeI, using the blunt/TA ligation master mix (New England Biolabs) at room temperature for 30 minutes. The DNA was then recovered by incubating with 0.6× Kapa SPRI beads (Kapa Biosystems) for 5 minutes, capturing the beads with a magnetic rack, washing twice with 80% ethanol, air drying the beads for 5 minutes and finally resuspending the DNA in 50 μL buffer 4 (50 mM potassium acetate, 20 mM Tris-acetate, 10 mM magnesium acetate, 100 μg/mL BSA, pH 7.9). DNA was then digested by addition of 20 units MmeI (New England Biolabs) and 40 pmol/μL SAM (S-adenosyl methionine) at 37° C. for 1 hour, followed by heat inactivation at 75° C. for 20 minutes. DNA was then ligated to 30 pmoles T7 adapter using the blunt/TA ligation master mix (New England Biolabs) at room temperature for 30 minutes. DNA was then recovered using a PCR cleanup kit (Zymo) and eluted in 20 μL buffer 4, then digested with 20 units of BsaXI for 1 hour at 37° C. The guide RNA stem-loop sequences were added by adding 15 pmoles stem-loop adapter and using the blunt/TA ligation master mix (New England Biolabs) at room temperature for 30 min. DNA was then recovered using a PCR cleanup kit (Zymo), eluted in 20 μL elution buffer and PCR amplified using HiFidelity 2× master mix (New England Biolabs). Primers T7-Ad1 and gRU (sequence 5′>3′ AAAAAAGCACCGACTCGGTG) (SEQ ID NO: 4419) were used to amplify with the following settings (98° C. 3 min; 98° C. for 20 sec, 60° C. for 30 secs, 72° C. for 20 sec, 30 cycles). The PCR amplicon was cleaned up using the PCR cleanup kit and verified by DNA sequencing, then used as template for an in vitro transcription reaction to generate guide RNAs.

Example 5: Use of BaeI/EcoP15I Adapter

Adapter BaeI/EcoP15I was made by combining 2 moles of BE Ad1 and BE Ad2 in 40 μL water. T7-E adapter was made by combining 1.5 μmoles of T7-Ad3 and T7-Ad4 oligos in 100 μL water. In all cases, after mixing adapters were heated to 98° C. for 3 min then cooled to room temperature at a cooling rate of 1° C./min in a thermal cycler.

TABLE 6 Oligonucleotides used with BaeI/EcoP15I Adapter. SEQ Oligo ID NO: name Sequence (5 > 3) Modification 4416 BE ActgctgacACAAgtatcTTTTTTTTTTgtttaaacTTTTTTTTTT 5′phosphate Ad1 gatacACAAgtcagcagA 4416 Be TctgctgacTTGTgtatcAAAAAAAAAAgtttaaacAAAAAAAAAA 5′phosphate Ad2 gatacTTGTgtcagcagT  12 T7- gcctcgagctaatacgactcactatagag none Ade 4417 T7- NNctctatagtgagtcgtatta 5′phosphate Ad4 4418 stIgR ttagagctagaaatagcaagttaaaataaggctagtccgttatcaa 5′adenylation cttgaaaaagtggcaccgagtcggtgctttttt

The DNA containing the CCD blunt ends (from earlier section) was then ligated to 50 pmoles of adapter BaeI/EcoP15I, using the blunt/TA ligation master mix (New England Biolabs) at room temperature for 30 minutes. The DNA was then recovered by incubating with 0.6× Kapa SPRI beads (Kapa Biosystems) for 5 minutes, capturing the beads with a magnetic rack, washing twice with 80% ethanol, air drying the beads for 5 minutes and finally resuspending the DNA in 50 μL buffer 4 (50 mM potassium acetate 20 mM Tris-acetate, 10 mM magnesium acetate, 100 μg/mL BSA, pH 7.9). Recovered DNA was then digested with 20 units PmeI for 30 min at 37° C.; DNA was then recovered by incubating with 1.2× Kapa SPRI beads (Kapa Biosystems) for 5 minutes, capturing the beads with a magnetic rack, washing twice with 80% ethanol, air drying the beads for 5 minutes and finally resuspending the DNA in 50 μL buffer 4. These steps eliminate small (<100 nucleotides) DNA and BaeI/EcoP15I adapter multimers.

DNA was then digested by addition of 20 units EcoP15I (New England Biolabs) and 1 mM ATP at 37° C. for 1 hour, followed by heat inactivation at 75° C. for 20 minutes. DNA was then ligated to 30 pmoles T7-E adapter using the blunt/TA ligation master mix (New England Biolabs) at room temperature for 30 minutes. DNA was then recovered using a PCR cleanup kit (Zymo) and eluted in 20 μL buffer 4.

Purified DNA was then digested by adding 20 units of BaeI (New England Biolabs), 40 pmol/μL SAM (S-adenosyl methionine) and incubating at 37° C. for 1 hour to eliminate both the adapter derived sequences and the CCD (and complementary HGG) motifs. DNA was then recovered using a PCR cleanup kit (Zymo) and eluted in 20 μL elution buffer.

Recovered DNA was then ligated to the stlgR oligo using Thermostable 5′ AppDNA/RNA Ligase

(New England Biolabs) by adding 20 units ligase, 20 pmol stlgR oligo, in 20 μL ss ligation buffer (10 mM Bis-Tris-Propane-HCl, 10 mM MgCl₂, 1 mM DTT, 2.5 mM MnCl₂, pH 7 @ 25° C.) and incubating at 65° C. for 1 hour followed by heat inactivation at 90° C. for 5 min. DNA product was then PCR amplified using HiFidelity 2× master mix (New England Biolabs). Primers T7-Ad3 and gRU (sequence 5′>3′ AAAAAAGCACCGACTCGGTG) (SEQ ID NO: 4419) were used to amplify with the following settings (98° C. 3 min; 98° C. for 20 sec, 60° C. for 30 secs, 72° C. for 20 sec, 30 cycles). The PCR amplicon was cleaned up using the PCR cleanup kit and verified by DNA sequencing, then used as template for an in vitro transcription reaction to generate the guide RNAs.

Example 6: NEMDA Method

NEMDA (Nicking Endonuclease Mediated DNA Amplification) was performed using 50 ng of human genomic DNA. The DNA was incubated in 100 μL thermo polymerase buffer (20 mM Tris-HCl, 10 mM (NH₄)₂SO₄, 10 mM KCl, 6 mM MgSO₄, 0.1% Triton® X-100, pH 8.8) supplemented with 0.3 mM dNTPs, 40 units of Bst large fragment DNA polymerase, and 0.1 units of NtCviPII (New England Biolabs) at 55° C. for 45 min, followed by 65° C. for 30 min and finally 80° C. for 20 min in a thermal cycler.

The DNA was then diluted with 300 μL of buffer 4 supplemented with 200 pmoles of T7-RND8 oligo (sequence 5′>3′ gcctcgagctaatacgactcactatagagnnnnnnnn) (SEQ ID NO: 4420) and boiled at 98° C. for 10 min followed by rapid cooling to 10° C. for 5 min. The reaction was then supplemented with 40 units of E. coli DNA polymerase I and 0.1 mM dNTPs (New England Biolabs) and incubated at room temperature for 20 min followed by heat inactivation at 75° C. for 20 min. DNA was then recovered using a PCR cleanup kit (Zymo) and eluted in 30 μL elution buffer.

DNA was then ligated to 50 pmoles of adapter BaeI/EcoP15I, using the blunt/TA ligation master mix (New England Biolabs) at room temperature for 30 minutes. The DNA was then recovered by incubating with 0.6× Kapa SPRI beads (Kapa Biosystems) for 5 minutes, capturing the beads with a magnetic rack, washing twice with 80% ethanol, air drying the beads for 5 minutes and finally resuspending the DNA in 50 μL buffer 4 (50 mM potassium acetate, 20 mM Tris-acetate, 10 mM magnesium acetate, 100 μg/mL BSA, pH 7.9). Recovered DNA was then digested with 20 units PmeI for 30 min at 37° C.; DNA was then recovered by incubating with 1.2× Kapa SPRI beads (Kapa Biosystems) for 5 minutes, capturing the beads with a magnetic rack, washing twice with 80% ethanol, air drying the beads for 5 minutes and finally resuspending the DNA in 50 μL buffer 4. These steps eliminate small (<100 nucleotides) DNA and BaeI/EcoP15I adapter multimers.

Purified DNA was then digested by adding 20 units of BaeI (New England Biolabs), 40 pmol/μL SAM (S-adenosyl methionine) and incubating at 37° C. for 1 hour to eliminate both the adapter derived sequences and the CCD (and complementary HGG) motifs. DNA was then recovered using a PCR cleanup kit (Zymo) and eluted in 20 μL elution buffer.

Recovered DNA was then ligated to the stlgR oligo using Thermostable 5′ AppDNA/RNA Ligase (New England Biolabs) by adding 20 units ligase, 20 pmol stlgR oligo, in 20 μL ss ligation buffer (10 mM Bis-Tris-Propane-HCl, 10 mM MgCl₂, 1 mM DTT, 2.5 mM MnCl₂, pH 7 @ 25° C.) and incubating at 65° C. for 1 hour followed by heat inactivation at 90° C. for 5 min. DNA product was then PCR amplified using HiFidelity 2× master mix (New England Biolabs). Primers T7-Ad3 (sequence 5′>3′ gcctcgagctaatacgactcactatagag) (SEQ ID NO: 12) and gRU (sequence 5′>3′ AAAAAAGCACCGACTCGGTG) (SEQ ID NO: 4419) were used to amplify with the following settings (98° C. for 3 min; 98° C. for 20 sec, 60° C. for 30 secs, 72° C. for 20 sec, 30 cycles). The PCR amplicon was cleaned up using the PCR cleanup kit and verified by DNA sequencing, then used as template for an in vitro transcription reaction to generate the guide RNAs. 

The invention claimed is:
 1. A method of making a collection of nucleic acids for a nucleic acid-guided nuclease system protein comprising at least 10⁵ unique guide nucleic acids (gNAs), each comprising a DNA comprising a targeting sequence ligated to a DNA comprising a nucleic acid-guided nuclease system protein-binding sequence, comprising: a. providing a plurality of double-stranded DNA molecules comprising at least 10⁵ unique sequences of interest, each comprising a sequence of interest 5′ to a PAM sequence, and its reverse complementary sequence on the opposite strand, wherein the sequence of interest or its reverse complementary sequence corresponds to a targeting sequence; b. performing an enzymatic digestion reaction on the plurality of double stranded DNA molecules, wherein cleavages are generated at the PAM sequence and/or its reverse complementary sequence on the opposite strand, but without completely removing the PAM sequence and/or its reverse complementary sequence on the opposite strand from the double stranded DNA; c. ligating adapters comprising a recognition sequence to a plurality of the resulting DNA molecules of step (b); d. contacting the DNA molecules of step (c) with a restriction enzyme that recognizes the recognition sequence of step (c), whereby generating DNA fragments comprising blunt-ended double strand breaks immediately 5′ to the PAM sequence, whereby removing the PAM sequence and the adapter containing the enzyme recognition site; and e. ligating the resulting double stranded DNA fragments of step (d) with a DNA comprising a nucleic acid-guided nuclease system protein-binding sequence, whereby generating a plurality of DNA fragments, each comprising a DNA comprising a targeting sequence ligated to a DNA comprising a nucleic acid-guided nuclease system protein-binding sequence, wherein the plurality of DNA fragments comprises at least 10⁵ unique targeting sequences.
 2. The method of claim 1, wherein the nucleic acid-guided nuclease system protein is a CRISPR/Cas system protein.
 3. The method of claim 1, wherein the double stranded DNA molecules further comprise a regulatory sequence upstream of the sequence of interest 5′ to the PAM sequence.
 4. The method of claim 3, wherein the regulatory sequence comprises a promoter.
 5. The method of claim 4, wherein the promoter comprises a T7, Sp6, or T3 sequence.
 6. The method of claim 1, wherein the double stranded DNA molecules are genomic DNA, intact DNA, or sheared DNA.
 7. The method of claim 6, wherein the genomic DNA is human, mouse, avian, fish, plant, insect, bacterial, or viral.
 8. The method of claim 1, wherein the DNA segments comprising a targeting sequence are at least 22 bp.
 9. The method of claim 1, wherein the DNA segments comprising a targeting sequence are 15-250 bp in size range.
 10. The method of claim 1, wherein the PAM sequence is AGG, CGG, or TGG.
 11. The method of claim 1, wherein the PAM sequence is specific for a CRISPR/Cas system protein selected from the group consisting of Cas9, Cpf1, Cas3, Cas8a-c, Cas10, Cse1, Csy1, Csn2, Cas4, Csm2, and Cm5.
 12. The method of claim 1, wherein step (b) further comprises (1) contacting the double stranded DNA molecules with an enzyme capable of creating a nick in a single strand at a CCD site, whereby generating a plurality of nicked double stranded DNA molecules, each comprising a sequence of interest followed by an HGG sequence, wherein the double stranded DNA molecules are nicked at the CCD sites; and (2) contacting the nicked double stranded DNA molecules with an endonuclease, whereby generating a plurality of double stranded DNA fragments, each comprising a sequence of interest followed by an HGG sequence wherein residual nucleotides from HGG and/or CCD sequences is (are) left behind.
 13. The method of claim 1, wherein step (d) further comprises PCR amplification of the adaptor-ligated DNA fragments from step (c) before cutting with the restriction enzyme recognizing the recognition sequence of step (c), wherein after PCR, the recognition sequence is positioned 3′ of the PAM sequence, and a regulatory sequence is positioned at the 5′ distal end of the PAM sequence.
 14. The method of claim 1, wherein the enzymatic digestion reaction comprises a first and a second nicking enzyme.
 15. The method of claim 1, wherein step (c) further comprises a blunt-end reaction with a T4 DNA Polymerase, if the adapter to be ligated does not comprise an overhang.
 16. The method of claim 1, wherein the adapter of step (c) is either (1) double stranded, comprising a restriction enzyme recognition sequence in one strand, and a regulatory sequence in the other strand, if the adapter is Y-shaped and comprises an overhang; or (2) has a palindromic enzyme recognition sequence in both strands, if the adapter is not Y-shaped.
 17. The method of claim 1, wherein the restriction enzyme of step (d) is MlyI.
 18. The method of claim 1, wherein step (d) further comprises contacting the DNA molecules with an XhoI enzyme.
 19. The method of claim 1, wherein in step (e) the DNA comprising a nucleic acid-guided nuclease system protein-binding sequence encodes for a RNA comprising the sequence (SEQ ID NO: 1) GUUUUAGAGCUAGAAAUAGCAAGUUAAAAUAAGGCUAGUCCGUUAUCAA CUUGAAAAAGUGGCACCGAGUCGGUGCUUUUUUU or encodes for a RNA comprising the sequence (SEQ ID NO: 2) GUUUUAGAGCUAUGCUGGAAACAGCAUAGCAAGUUAAAAUAAGGCUAGU CCGUUAUCAACUUGAAAAAGUGGCACCGAGUCGGUGCUUUUUUUC.


20. The method of claim 1, wherein the sequences of interest are from an organism, and wherein the sequences of interest are spaced every 10,000 bp or less across the genome of the organism.
 21. The method of claim 14, wherein the first nicking enzyme is a Nt.CviPII enzyme, and the second nicking enzyme is a T7 Endonuclease I enzyme. 